Preamble
In the field
of research and development of marine two stroke diesel engine it was a decade
of remarkable landmarks. Camshaft-controlled
diesel engines have been the state of the art ever since the birth of
reciprocating machinery and have been refined and developed ever since.
However, a mechanical cam is fixed once made and, in spite of various
mechanical and hydraulic add-on devices like VIT, etc., timing control possibilities
are limited with mechanical cams. Not least fuel injection pressure control and
variation over the load range have limitations with a camcontrolled engine.
Therefore, the main purpose of changing
to electronic control is to ensure fuel injection timing and rate, as well as
the exhaust valve timing and operation, exactly when and as desired.
Especially
with respect to the fuel injection rate, the control system has been so
designed that it is possible to maintain a rather high injection pressure also
at low load, without the limitation from the camshaft-controlled engine, where
this would result in too high pressure at high load. Both the ‘cam angle,
inclination and length’ are electronically variable.
The
major competitors in marine diesel engines like Wartzila NSD, MAN B &
W and Mitsubishi UEC have developed revolutionary
models with principle differeces of their design and operational concepts are compared in the
following chapters
ME Engines – the New Generation of Diesel Engines
INTRODUCTION
The electronic control of the engine
fuel injection and exhaust valves improves low-load operation, engine
acceleration, and give better engine balance and load control, leading to
longer times between overhauls, also by implementation of enhanced diagnostics
systems. It will give lower fuel consumption, lower cylinder oil consumption
and, not least, better emission characteristics, particularly with regard to
visible smoke and NOx, see Fig. 3 for a summary.
The ME engine features electronic
control of the cylinder lube oil feed, by having our proprietary Alpha
Lubricators integrated in the system. With the Alpha Lubrication system, about
0.3 g/bhph cyl. oil can be saved, compared with engines with mechanical
lubricators.
For the ME engines, the electronic
control system has been made complete. Hence, the ME engine features fully
integrated control of all functions like the governor, start and reversing,
fuel, exhaust and starting valves, as well as cylinder oil feeding, as summarised in Fig. 4.
ELEMENTS
OF THE ME-C ENGINE
The mechanical difference between an
MC-C engine and its electronically controlled counterpart, the ME-C engine,
constitutes a number of mechanical parts made redundant and replaced by
hydraulic and mechatronic parts with enhanced functions, as illustrated in Fig.
5 and summarised below:
The following
parts are omitted:
·
Chain
drive
·
Chain
wheel frame
·
Chain
box on frame box
·
Camshaft
with cams
·
Roller
guides for fuel pumps and exhaust valves
·
Fuel
injection pumps
·
Exhaust
valve actuators
·
Starting
air distributor
·
Governor
·
Regulating
shaft
·
Mechanical
cylinder lubricator
·
Local
control stand
The
above-mentioned parts are replaced by:
·
Hydraulic
Power Supply (HPS)
·
Hydraulic
Cylinder Units (HCU)
·
Engine
Control System (ECS), controlling the following:
Ø Electronically
Profiled Injection (EPIC)
Ø Exhaust valve
actuation
Ø Fuel oil
pressure boosters
Ø Start and
reversing sequences
Ø Governor
function
Ø Starting air
valves
Ø Auxiliary
blowers
·
Crankshaft
position sensing system
·
Electronically
controlled Alpha Lubricator
·
Local
Operating Panel (LOP)
Fig. 6 shows how the necessary power for
fuel injection and exhaust valve operation – previously provided via the chain
drive – is now provided from a Hydraulic Power Supply (HPS) unit located at the
front of the engine at bedplate level.
The main components of the Hydraulic Power
Supply unit are the following:
·
Self
cleaning filter with 10-micron filter mesh
·
Redundancy
filter with 25-micron filter mesh
· Start up pumps: High-pressure pumps with supply pressure of
175 bar
Low-pressure pumps for filling the exhaust
valve push rod with supply
pressure
of 4 bar
·
Engine
driven axial piston pumps supplying high pressure oil to the Hydraulic
Cylinder Unit with oil pressures up to
250 bar.
Before
engine start, the hydraulic oil pressure used in the mechanical/hydraulic
system (for controlling the actuators) is generated by electrically driven
start-up pumps. After start, the engine driven pump will take over the supply.
The engine driven pumps are gear or
chain driven, depending on engine size. If so preferred, all pumps can also be
electrically driven. The hydraulic pumps are axial piston pumps with flow
controlled by the integrated control system. There are three engine driven
pumps, but actually only two are needed for operation. Second-order moment
compensators, where needed, can be integrated into the pump drive.
Alternatively, electrically driven compensators can be used. If so preferred,
the entire hydraulic oil system can be made as a separate, independent system.
Fig. 7 shows the entire hydraulic oil
loop with the hydraulic power supply system and, as can be seen, the generated
servo oil is fed via double-walled piping to the Hydraulic Cylinder Units of
which there is one per cylinder, mounted on a common base plate on the top
gallery level on the engine, as illustrated in Fig. 8 and detailed in Fig. 9.
In this latter image, also the important electronic control valves, i.e. the
ELFI (a proportional ELectronic Fuel Injection control valve) and the ELVA (an
on-off Electronic exhaust Valve Actuator) are shown.
The Hydraulic Cylinder Unit furthermore
comprises a hydraulic oil distribution block withpressure accumulators, the
exhaust valve actuator, with ELVA and a fuel oil pressure booster with ELFI,
raising the fuel oil supply pressure during injection from the 10-bar supply
pressure to the specified load-dependent injection pressure of 600-1000 bar.
Permanent high pressure with preheated fuel oil on top of the engine is thereby
avoided, without losing any advantage of highpressure injection.
Figs. 10 and 11 show the per cylinder
fuel oil injection system, and Fig. 12 shows theindividual components of the
fuel oil pressure booster. As will appear, the fuel oil pressure booster is
mechanically much more simple than the traditional fuel pump with roller,
roller guide, VIT and cut-off wedges. Figs. 12 and 13 outline the media and
plunger movements in respect to a signal to the ELFI from the engine control
system, Fig. 14 shows the impeccable condition of the parts after about 4,000
hrs. of operation. Now more than 10,000 hrs have been logged, and the results
are still the same. There has been virtually nothing to report. The fuel oil
pressure booster is less exposed to wear than a traditional fuel oil pump and,
with its significantly larger sealing length (compared with the conventional
Bosch-type fuel pumps), a much longer lifetime can be expected.
Fig. 15 explains in detail how the
actuator for the exhaust valve responds to the electronic actuator signal from
the engine control system.
Another system that benefits from
mechanical simplification by being electronically rather than mechanically
controlled on the ME engine is the starting air system, Fig. 16. The mechanical
starting air distributor is past history.
The Alpha Lubricator system for cylinder
oil feed rate control, already with more than 200 sets sold, benefits in the ME
engine version by using the 200-bar servo oil pressure as driving force rather
than a separate pump station used in the stand-alone systems. The ME execution,
therefore, as illustrated in Fig. 17, separates the cylinder oil from the servo
oil. As shown in Fig. 18 (and Fig. 7), the Alpha Lubricator is mounted on the
hydraulic oil distribution block. he ME engine control system, simplified in
Fig. 19 and with more details in Fig. 20, is designed with the principle that
no single failure of anything shall make the engine inoperative. Therefore, all
essential computers are with a hot stand-by.
All the computers in the system, referred
to as Engine Interface Control Unit, Engine Control Units, Cylinder Control
Units and Auxiliary Control Units, are of exactly the same execution and can
replace each other, in that they will adapt to the desired functionality of the
particular location once installed, including if replaced by a spare. The
computer, often referred to as a Multi-Purpose Controller, is a proprietary
in-house development of MAN B&W Diesel. Thus, we can ensure spare part
deliveries over the engine’s lifetime. The Local Operating Panel, incl.
Cylinder Control and Auxiliary Control Units, see Fig. 21, is mounted on the
middle gallery of the 7S50ME-C made in Denmark.
The Control Units can, of course, also be located elsewhere.
As to installation aspects, Fig. 22
illustrates that, apart from the cabling of the control network, an ME-C engine
and an MC-C engine are practically the same for a shipyard, as detailed below:
·
Overhaul
height: same
·
Engine
seating: same
·
Engine
outline: modifications with no influence for yard
·
Engine
weight: slightly reduced
·
Engine
pipe connection: back flush from filter on engine added, other connections
are
unchanged
·
Gallery
outline: slight modifications
·
Top
bracing exhaust side: same
·
Capacity
of auxiliary machinery: same
·
Lubricating
oil system: slightly modified
·
Specification
and installation of governor omitted
·
Other
systems: same
·
Cabling:
cables added for communication and network
Actually, there is a small
simplification, as illustrated in Fig. 23, in that the tooling for the exhaust
valve system and fuel oil pressure booster system is simpler.
FEATURES
OF THE ME-C ENGINE
As mentioned in the introduction, the
purpose of making electronic engines is focused around the virtues related to
“ensuring fuel injection and rate, as well as exhaust valve timing exactly when
and as desired”.
With respect to the exhaust valve
movement, this means changing the ‘cam length’, asillustrated in Fig. 24, by
simply changing the point in time of activating the ELVA valve . This can be
used to control the energy to the turbocharger, both during steady and
transient load conditions. Smoke-free acceleration is a natural benefit apart
from SFOC optimization at any load. Fig. 25 gives an illustration of how
already a ‘different cam length’ was implemented on the 7S50ME-C engine in
Frederikshavn for 100% load vs. 75% load.
Thanks to the multitude of possibilities
with the ELFI, the proportional valve controlling the servo oil pressure to the
fuel oil pressure booster, not only the fuel oil ‘cam length’, but also the
‘cam inclination and angle’ and even the number of activations per stroke can
be varied for the fuel oil injection.
Fig. 26 illustrates different profiles
demonstrated during testing of the 7S50ME-C. The double injection profile is
specially tailored for a significant reduction of NOxemissions as referred to
later (see Fig. 32).
Fig. 27 shows the selected injection
rate on that engine at 75% load, compared with what it would have been with a
fixed cam. The resulting heat release, see Fig. 28, is the reason for selecting
a more intensive injection. A better heat release mirrors a better fuel
consumption, also because the pmax is higher, see Fig. 29. Such data could of
course also be realised on a mechanical engine, but not while at the same time
maintaining the ability to perform at 100% load. In the low end of the load
scale, the possibility for controlling the timing and rate of injection gives
the possibility to demonstrate stable running down to 10% of MCR-rpm, i.e. 13
rpm against a
water
brake only. This could be even more stable against a propeller eliminating the
need for stop-and-go operation through channels and canals and making ME
engines particularly suitable for shuttle tankers and lightering vessels, as
well as for vessels with greatly varying load profile.
General performance curves for the ME-C
and MC-C engines are shown in Fig. 30. The lower part load fuel consumption is
achieved by raising the pmax over the whole load range. In order to avoid too
high difference between pmax and pcomp, also this pressure is raised by timing
control.
As also illustrated, the lower SFOC
comes at a price in that the NOx increases. For this reason, the first two
modes to be incorporated in the control system of the ME engine, as standard,
are the ‘fuel economy mode’ and the ‘low-NOx’ mode. Fig. 31 illustrates the
coagency between SFOC, NOx, and pmax/Pcomp for the two modes.
It goes without saying that an ME-C
engine will comply with IMO’s NOx cap also in the fuel economy mode.
The low-NOx mode is intended for areas
where lower than IMO NOx limits do or will apply.
The change from one mode to the other is
a matter of seconds only and, of course, is done while running, as illustrated
in Fig. 32.
SUMMARY
The advantages of the ME-C range of
engines are quite comprehensive, as seen below:
·
Lower
SFOC and better performance parameters thanks to variable electronically
controlled
timing of fuel injection and exhaust valves at any load
·
Appropriate
fuel injection pressure and rate shaping at any load
·
Improved
emission characteristics, with lower NOx and smokeless operation
·
Easy
change of operating mode during operation
·
Simplicity
of mechanical system with wellproven traditional fuel injection technology
familiar to any crew
·
Control
system with more precise timing, giving better engine balance with equalized
thermal load in and between cylinders
·
System
comprising performance, adequate monitoring and diagnostics of engine for
longer time between overhauls
·
Lower
rpm possible for manoeuvring
·
Better
acceleration, astern and crash stop performance
·
Integrated
Alpha Cylinder Lubricators
·
Up-gradable
to software development over the lifetime of the engine
It is a natural consequence of the above
that many more features and operating modes are feasible with our fully
integrated control system and, as such, will be retrofittable and eventually
offered to owners of ME-C engines.
Against this background, we are proud to
present our ME-C engine programme, as
shown
in Fig. 33.
All figures
mentioned above is given below
Fig. 1: 7S50ME-C, MAN B&W Diesel, Denmark, February
2003
Fig. 2:
Electronically Controlled Engines, precise control
Fig. 3:
Electronically Controlled Engines, improved features
Fig. 4:
Electronically Controlled Engines, fully integrated control
Fig. 5: From
MC-C to ME-C – Mechanical Differences
Fig. 6:
Hydraulic Power Supply (HPS)
Fig. 7: ME-C
Engines, Hydraulic Oil Loop
Fig. 8:
Hydraulic Cylinder Units (HCU)
Fig. 9:
Hydraulic Cylinder Unit (HCU)
Fig. 10: Fuel Injection
System
Fig. 11: Fuel
Injection System
Fig. 12: Fuel
Oil Pressure Booster
Fig. 13: Fuel
Oil Pressure Booster
Fig. 14: Fuel
Oil Pressure Booster Actuator
Fig. 15: Exhaust
Valve Actuator
Fig. 16: ME
Starting Air System
Fig. 17: Alpha
Lubricator for ME Engine
Fig. 18: Alpha
Lubricator System for ME
Fig. 19: ME
Engine Control System
Fig. 20:
Configuration of Control System
Fig. 21: Local
Operating Panel (LOP)
Fig. 22:
Installation Aspects, ME Engine
Fig. 23: ME –
Maintenance Aspects
Fig. 24: Exhaust
Valve Timing
Fig. 25: Exhaust
Valve Closing Time
Fig. 26:
Injection Profiles
Fig. 27:
Injection at 75% load, ME-C versus MC-C
Fig. 28: Heat
Release at 75% load, ME-C versus MC-C
Fig. 29:
Cylinder Pressures at 75% load, ME-C versus MC-C
Fig. 30:
Performance Curves, ME-C versus MC-C
Fig. 31:
Performance Curves, Economy versus low-NOx
Fig. 32:
7S50ME-C – 75% load
Fig. 33: ME
Engine Programme
chapter-2
The Intelligent Engine concept
ADVANTAGES
Ø on-line
monitoring ensures uniform load distribution among cylinders
Ø an active
on-line overload protection system prevents thermal overload
Ø early warning of
faults under development, triggering countermeasures - significantly improved
low load operation.
• Enhanced emission
control flexibility:
Ø emission
performance characteristics optimised to meet local demands
Ø later updating possible.
• Reduced fuel and lube
oil consumption:
Ø engine
performance fuel-optimised at ‘all’ load conditions
Ø ‘as new’
performance easily maintained over the engine lifetime
Ø mechatronic
cylinder lubricator with advanced dosage control.
The Intelligent Engine
Concept
To
meet the operational flexibility target, it is necessary to have great
flexibility in the operation of – at least – the fuel injection and exhaust
valve systems. Achieving this objective with cam-driven units would require
substantial mechanical complexity that would hardly contribute to engine
reliability.
To
meet the reliability target, it is necessary to have a system that can protect
the engine from damage due to overload, lack of maintenance, mal-adjustment,
etc. A condition monitoring system must be used to evaluate the general engine
condition so as to maintain the engine performance and keep its operating
parameters within the prescribed limits and to keep it up to ‘as new’ standard
over the lifetime of the engine.
The
above indicates that a new type of drive has to be used for the injection pumps
and the exhaust valves and that an electronic control and monitoring system
will also be called for. The resulting concept is illustrated in Fig. 1.
The
upper part shows the Operating Modes which may be selected from the bridge
control system or by the intelligent engine’s own control system. The control
system contains data for optimal operation in these modes, which consist of a number of single modes
corresponding, for instance, to different engine loads and different required
emission limits.
The
fuel economy modes and emission controlled modes (some of which may incorporate
the use of an SCR catalytic clean-up system) are selected from the bridge. The
optimal reversing/crash stop modes are selected by the electronic control
system itself when the bridge control system requests the engine to carry out
the corresponding operation.
The
engine protection mode is, in contrast, selected exclusively by the condition
monitoring and evaluation system, regardless of the current operating mode.
Should this happen in circumstances where, for instance, reduced power is
unacceptable for reasons of the safety of the ship, the protection mode can be
cancelled from the bridge.
The
centre of Fig.1 shows the brain of the system: the electronic control system.
This analyses the general engine condition and controls the operation of the
following engine systems (shown in the lower part of Fig. 1): the fuel
injection system, the exhaust valves, the cylinder lubrication system and the
turbo charging system.
Some
of the control functions for these units are, as mentioned above, pre-optimised
and can be selected from the bridge.
Other control functions are selected by the engine condition monitoring system
on the basis of an analysis of various input from the units on the left and
right sides of Fig. 1: general engine performance data, cylinder pressure,
cylinder condition monitoring data and output from the Load Control Unit. More
detailed descriptions of these systems can be found in Ref. [1].
Fig. 1: The Intelligent Engine concept
The
Condition Monitoring and Evaluation System is an on-line system with automatic
sampling of all “normal” engine performance data, supplemented by cylinder
pressure measurements, utilising our CoCoS-EDS system. When the data-evaluation
system indicates normal running conditions, the system will not interfere with
the normal pre-determined optimal operating modes. However, if the analysis
shows that the engine is in a generally unsatisfactory condition, general
countermeasures will be initiated for the engine as a unit. For instance, if
the exhaust gas temperature is too high, fuel injection may be retarded and/or
the exhaust valves may be opened earlier, giving more energy to the
turbocharger, thus increasing the amount of air and reducing the exhaust gas
temperature.
At
all events, the system reports the unsatisfactory condition to the operator
together with a fault diagnosis, a specification of the countermeasures used or
proposed, and recommendations for the operation of the engine until normal
conditions can be re-established or repairs can be carried out. The 4T50MX
research engine in our R&D Centre in Copenhagen was operated from 1993 to
1997 with the first-generation Intelligent Engine (IE) system. The engine has
been running with this system for the IE development as well as for its normal
function as a tool for our general engine
Fig. 2:
Second-generation ‘Intelligent Engine’ system fitted to the 4T50MX research
engine in 1997
development. The 1990
running hours logged during that period of time has provided us with
significant experience with this system. Being the first generation of IE, the
system was somewhat ‘over-engineered’ and relatively costly compared with the
contemporary camshaft system. On the other hand, the system offered much
greater flexibility, which has proved its value in the use of the research
engine as one of our most important development tools.
In
1997, the engine was fitted with second-generation IE systems, please refer to
Fig. 2 showing the fuel injection and exhaust valve actuating systems on the
engine. The second-generation systems, to be described in more detail in the
following, have been developed in order to:
•
simplify the systems and tailor them to the requirements of the engine
•
facilitate production and reduce the costs of the IE system
•
simplify installation and avoid the use of special systems wherever possible.
On
the electronic software/hardware side, the original first-generation system was
used for a start. Since then, significant development efforts have been invested
in transforming the electronic part of the IEsystem into a modular system,
where some of the individual modules can also be used in conventional engines.
This means development of a new computer unit and large software packages –
both of which have to comply with the demands of the Classification Societies
for marine applications.
Design Features of the
Second-Generation IE System
General description
The
principle layout of the new system, replacing the camshaft system of the
conventional engine, is illustrated in Fig. 3. The system comprises an
enginedriven high-pressure servo oil system, which provides the power for the
hydraulically operated fuel injection and exhaust valve actuation units on each
cylinder. Before the engine is started, the hydraulic power system (or servo
oil system) is pressurised by means of a small electrically driven
high-pressure pump.
Furthermore,
the starting air system and the cylinder lubrication system have been changed
compared with the conventional engine series. A all these units.
The
following description will outline the main features of these systems, together
with our recent development work and experience.
Power
supply system
Engine-driven
multi-piston pumps supply high-pressure lube oil to provide the necessary power
for fuel injection and exhaust valve actuation and thus replace the camshaft
power-wise. The multi-piston pumps are conventional, mass-produced axial piston
pumps with proven reliability.
The use of engine
system oil as the activating medium means that a separate hydraulic oil system
is not needed, thus extra tanks, coolers, supply pumps and a lot of piping etc.
can be dispensed with. However, generally the engine system oil is not clean
enough for direct use in high-pressure hydraulic systems, and it might be
feared that the required 6 µm filter would block up quickly.
We
have undertaken quite extensive development work in collaboration with a filter
supplier (B&K) in order to ensure the cleanliness required for such systems
– the very positive long-term results are described below.
Against
this background, and based on the fact that the clean lube oil from the engine
was at least as suitable for use in the hydraulic system as conventional
hydraulic oil, we decided to base our system on fine-filtered system lube oil.
This
is supplied from the normal system oil pumps, providing a higher inlet pressure
to the high-pressure pumps than otherwise – this being yet another benefit.
Fig. 3: System diagram for the hydraulic flow (servo
oil system)
Fuel injection system,
design features
The
general design of the system is shown in Fig. 4. A common rail servo oil system
using pressurised cool, clean lube oil as the working medium drives the fuel
injection pump. Each cylinder unit is provided with a servo oil accumulator to
ensure sufficiently fast delivery of servo oil in accordance with the
requirements of the injection system and in order to avoid heavy pressure
oscillations in the associated servo oil pipe system.
Fig.
4: General system layout for fuel injection and exhaust valve actuation systems
The movement of the plunger is
controlled by a fast-acting proportional control valve (a so-called NC valve),
developed by our cooperation partner Curtiss Wright Drive Technology GmbH
(formerly known as SIG Antriebstechnik) of Switzerland. The NC valve is, in turn, controlled by an
electric linear motor that gets its control input from the cylinder control
unit (see below).
This
design concept has been chosen in order to maximise reliability and
functionality – after all, the fuel injection system is the heart of the
engine, and its performance is crucial for fuel economy, emissions and general
engine performance. An example of the flexibility of the fuel injection system
will be given below.
The
key components have a proven reliability record: the NC valves have been in
serial production for some ten years and are based on high-performance valves
for such purposes as machine tools and sheet metal machines in car production –
applications where high reliability is crucial. The fuel njection pump features
well-proven fuel injection equipment technology, and the fuel valves are of our
well-proven and simple standard design.
As
can be seen in Fig. 5, the 2nd and 3rd generations of pump design are
substantially simpler than he 1st
generation design, the components are smaller, and they are very easy to
manufacture. By mid-2000, the 2nd generation pump had been in operation on the
4T50MX research engine for more than 1400 hours, whereas the 3rd generation is
starting service testing on the 6L60MC (see below)
The
major new design feature for the 3rd generation pump is its ability to operate
on heavy fuel oil. he pump plunger is
equipped with a modified umbrella design to prevent heavy fuel oil from
entering the lube oil system. The driving piston and the injection plunger are
simple and are kept in contact by the fuel pressure acting on the plunger, and
the hydraulic oil pressure acting on the driving piston. The beginning and end
of the plunger stroke are both controlled solely by the fast acting hydraulic
valve (NC valve), which is computer controlled.
Fig.
5: Design development of fuel injection pumps
Fuel injection system,
rate shaping capability
The
optimum combustion (thus also the optimum thermal efficiency) requires an
optimised fuel injection pattern which is generated by the fuel injection cam
shape in a conventional engine. Large two-stroke engines are designed for a
specified max. firing pressure, and the fuel injection timing is controlled so
as to reach that firing pressure with the given fuel injection system (cams,
pumps, injection nozzles, etc.).
For
modern engines, the optimum injection duration is around 18-20 degrees crank
angle at full load, and the max. firing pressure is reached in the second half
of that period. In order to obtain the best thermal efficiency, fuel to be
injected after reaching the max. firing pressure must be injected (and burnt)
as quickly as possible in order to obtain the highest expansion ratio for that
part of the heat released.
From
this it can be deduced that the optimum ‘rate shaping’ of the fuel injection is
one showing increasing injection rate
towards the end of injection, thus supplying the remaining fuel as quickly as
possible. This has been proven over many
years of fuel injection system development for our two-stroke marine diesel
engines, and the contemporary camshaft is designed accordingly.
The
fuel injection system for the Intelligent Engine is designed to do the same but
in contrast to the camshaft- based injection system, the IE system can be
optimised at a large number of load conditions.
Fig. 6: Comparison between the fuel injection
characteristics of the ME engine and a Staged Common Rail system in terms of
injection pressure, mass flow rate and flow distribution
Common Rail injection
systems with on/off control valves are becoming standard in many modern diesel
engines at present. Such systems are relatively simple and will provide larger
flexibility than the contemporary camshaft based injection systems. We do apply
such systems for controlling the high-pressure gas-injection in the dual-fuel
version of our MC engines, where the (two-circuit) common rail system provides the necessary
flexibility to allow for varying HFO/gas-ratios, please refer to [3].
Fig. 7: Fuel spray
distribution in the combustion chamber (schematically) corresponding to the
injection patterns illustrated in Fig. 6
However,
by nature the common rail system provides another rate shaping than what is
optimum for the engine combustion process. The pressure in the rail will be at
the set-pressure at the start of injection and will decrease during injection
because the flow out of the rail (to the fuel injectors) is much faster than
the supply of fuel into the rail (from high-pressure pumps supplying the
average fuel flow).
As
an example, an 8-cylinder engine will have a total ‘injection duration’ per
engine revolution of 160 deg. CA (8 x 20 degrees CA) during which the injectors
supply the same mass flow as the high-pressure supply pumps do during 360 deg.
CA. Thus, the outflow during injection is some 360/160 = 2.25 times the inflow
during the same period of time. Consequently, the rail pressure must drop
during injection, which is the opposite of the optimum rate shape. To
counteract this, it has been proposed to used ‘Staged Common Rail’ whereby the
fuel flow during the initial injection period is reduced by opening the fuel
valves one by one.
The
Rate Shaping with the IE system (using proportional control valves) and the
‘Staged Common Rail’ are illustrated in Fig. 6. This shows the injection
pressure, the mass flow and the total mass injected for each fuel valve by the
two systems, calculated by means of our advanced dynamic fuel injection
simulation computer code for a large bore engine (K98MC) with three fuel valves
per cylinder. In the diagram, the IEsystem is designated ME(this being the
engine designation, like 7S60ME-C). As can be seen, the Staged Common Rail
system supplies a significantly different injection amount to each of the three
fuel valves.
Fig.
8: Four examples of fuel injection pressures at the fuel valve, and the
corresponding fuel valve spindle lifting curves
Fig. 9: Effect of
injection pattern on combustion rate, NOx emission and specific fuel oil
consumption (test on 4T50MX research engine at 75% load)
Though
the Staged Common Rail system will provide a fuel injection rate close to the
optimum injection rate, combustion will not be optimal because the fuel is very
unevenly distributed in the combustion chamber whereas the combustion air is
evenly distributed. This is illustrated (somewhat overexaggerated to underline
the point) in Fig. 7: the valve opening first will inject the largest amount of
fuel and this will penetrate too much and reach the next fuel valve nozzle.
Experience
from older engine types indicates that this may cause a reliability problem
with the fuel nozzles (hot corrosion of the nozzle tip). The uneven fuel injection amount means that
there will be insufficient air for the fuel from the first nozzle, the correct
amount for the next and too much air for the third fuel valve. The average may
be correct but the result cannot be optimal for thermal efficiency and
emissions. Uneven heat load on the combustion chamber components can also be
foreseen - though changing the task of injecting first among the three valves
may ameliorate this.
Thus,
the IE injection system is superior to any Common Rail system – be it staged or
simple. Extensive testing has fully
confirmed that the IE fuel injection system can perform any sensible injection
pattern needed for operating the diesel engine. The system can perform as a
single-injection system as well as a pre-injection system with a high degree of
freedom to modulate the injection in terms of injection rate, timing, duration,
pressure, single/double injection, etc. In practical terms, a number of
injection patterns will be stored in the computer and selected by the control
system so as to operate the engine with optimal injection characteristics from
dead slow to overload, as well as during astern running and crash stop.
Change-over from one to another of the stored injection characteristics may be
effected from one injection cycle to the next.
Some
examples of the capability of the fuel injection system are shown in Fig. 8.
For each of the four injection patterns, the pressure in the fuel valve and the
needle-lifting curve are shown. Tests on the research engine with such patterns
(see Fig. 9) have confirmed that the ‘progressive injection’type (which
corresponds to the injection pattern with our optimised camshaft driven
injection system) is superior in terms of fuel consumption. The ‘double injection’
type gives slightly higher fuel
consumption, but some 20% lower NOx emission – with a very attractive
trade-off between NOx reduction and SFOC increase.
Fig. 10: Hydraulic
cylinder unit with fuel injection pump and exhaust valve actuator
Exhaust valve actuation
system
The
exhaust valve is driven by the same servo oil system as that for the fuel
injection system, using pressurised cool, clean lube oil as the working medium.
However, the necessary functionality of the exhaust valve comprises only
control of the timing of opening and closing the valve. This can be obtained by
using a simple fast-acting on/off control valve.
The
system features well-proven technology from the present engine series. The
actuator for the exhaust valve system is of a simple two-stage design, please
refer to Fig. 10. The first-stage actuator piston is equipped with a collar for
damping in both directions of movement. The second-stage actuator piston has no
damper of its own, and is in direct contact with a gear oil piston transforming
the hydraulic system oil pressure into oil pressure in the oil push rod. The
gear oil piston includes a damper collar that becomes active at the end of the
opening sequence, when the exhaust valve movement will be stopped by the
standard air spring.
Control system
Redundant
computers connected in a network provide the control functions of the camshaft
(timing and rate shaping) - please refer to Fig. 11. This new Engine Control System (see also [2]) is an
integrated part of the Intelligent Engine that brings completely new
characteristics to the engine. It comprises two Engine Control Units (ECU), a
Cylinder Control Unit (CCU) for each cylinder, a Local Control Terminal and an
interface for an external Application Control System. The ECU and the CCU have
both been developed as dedicated controllers, optimised for the specific needs
of the intelligent engine.
The
Engine Control Unit controls functions related to the overall condition of the
engine. It is connected to the Plant Control System, the Safety System and the
Supervision & Alarm System, and is directly connected to sensors and
actuators. The function of the ECU is to control the action of the following
components and systems:
Fig.
11: Control system for the Intelligent Engine
The engine speed in
accordance with a reference value from the application control system (i.e. an
integrated governor control)
•
Engine protection (overload protection as well as faults)
•
Optimisation of combustion to suit the running condition
•
Start, stop and reversing sequencing of the engine
•
Hydraulic (servo) oil supply (lube oil)
•
Auxiliary blowers and turbocharging.
The
Cylinder Control Unit is connected to all the functional components to be
controlled on each cylinder. Its function
is to control the activation of features like:
•
Fuel injection
•
Exhaust valve
•
Starting valve
•
Cylinder lubricator for the specific cylinder.
As
faults can never be completely ruled out, even with the best design of
electronic (or mechanical) components, the concept for the intelligent engine
has been designed with great care regarding fault tolerance and easy repair, to
ensure the continuous operation of the ship. Since each cylinder is equipped
with its own controller (the CCU), the worst consequence of a CCU failure is a
temporary loss of power from that particular cylinder (similar to, for
instance, a sticking fuel pump on a conventional engine). The engine controller
(ECU) has a second ECU as a hot stand-by which, in the event of a failure,
immediately takes over and continues the operation without any change in
performance (except for the decreased tolerance for further faults until repair
has been completed).
In
the event of a failure in a controller, the system will identify the faulty
unit, which is simply to be replaced with a spare. As soon as the spare is
connected, it will automatically be configured to the functions it is to
replace, and resume operation. As both the ECU and the CCU are implemented in
the same type of hardware, only a few identical spares are needed. If failures
occur in connected equipment – sensors, actuators, wires, etc. – the system
will locate the area of the failure and, through built-in guidance and test
facilities, assist the engine operating staff in the final identification of
the failed component.
Cylinder pressure
measuring system (PMI)
A
reliable measurement of the cylinder pressure is essential for ensuring ‘as
new’ engineer formance. A conventional mechanical indicator in the hands of a
skilled and dedicated crewmember can provide reasonable data. However, the
necessary process is quite time consuming and the cylinder pressure data
obtained in this way is not available for analysis in a computer, which means
that some valuable information is less likely to be utilised in a further
analysis of the engine condition. A computerized measuring system with a high
quality pressure pick-up connected to the indicator bore may provide this. We
have developed such a system, PMI Off-Line, of which more than 100 sets have
been sold for application on our conventional engines.
For
the Intelligent Engine, on-line measurements of the cylinder pressure are
necessary – or at least greatly desirable.
In this case, the indicator cock cannot be used since the indicator bore
will clog up after a few days of normal operation, making further measurements
useless.
Fig.
12: PMI on-line cylinder pressure sensor of the strain-pin type, built into the
cylinder cover, without contact with the corrosive combustion gases
Since
we realised this quite some time ago, we have been working on the development
of a reliable system for longterm continuous cylinder pressure measurements.
The first, successful, attempt involved the use of strain gauges on two cover
studs on each cylinder, thus in fact using the cylinder cover itself as a
‘pressure transducer’. A long-term test was carried out on the main engine of a
anish ferry about ten years ago, and the system provided us with stable
measurements over a period of more than 10,000 operating hours.
However,
there was some electrical noise in the signals, and we decided to use another
system that had been introduced on the market in the meantime: the strain-pin
type of pressure sensor. The pressure-sensing element is a rod located in a
bottom-hole in the cylinder cover, in close contact with the bottom of the
hole, close to the combustion chamber surface of the cylinder cover, as can be
seen in Fig. 12. Thus, the sensor measures the deformation of the cylinder
cover caused by the cylinder pressure without being in contact with the
aggressive combustion products and without having any indicator bore that can
clog up. The position of the sensor also makes it easier to prevent electrical
noise from interfering with the cylinder pressure signal.
The
pressure transducer of the off-line system is used for taking simultaneous
measurements for alibrating the on-line system. By feeding the two signals into
the computer in the calibration mode, a calibration curve is determined for
each cylinder. The fact that the same, high-quality, pressure ransducer is used
to calibrate all cylinders means that the cylinder-to-cylinder balance is not
at all influenced by differences between the individual pressure sensors.
The
on-line as well as the off-line system provide the user with unique assistance
for keeping the engine performance up to ‘as new’ standard and reduce the
workload of the crew. The systems automatically identify the cylinder being
measured without any interaction from the person carrying out the measurement
(because the system contains data for the engine’s firing order). Furthermore,
compensation for the crankshaft twisting is automatic, utilising proprietary
data for the engine design. If there is no such compensation, the mean
indicated pressure will be measured wrongly and when it is used to adjust the
fuel pumps, the cylinders will not have the same true uniform load after the
adjustment although it may seem so. Twisting of the crankshaft may lead to
errors in mean indicated pressure of some 5% if not compensated for!
Fig.
13: Example of PMI system output: cylinder balance table with recommended
adjustments
The computer carries out the tedious and
time-consuming work of evaluating the ‘indicator card’ data which are now in
computer files, and the cylinder pressure data can be transferred directly to
our CoCoS-EDS Engine Diagnosis System for inclusion in the general engine
performance monitoring. Furthermore, the result presented to the crew is far
more comprehensive and comprises a list of the necessary adjustments, as
illustrated in Fig. 13. These recommendations take into account that the
condition of the non-adjusted cylinders changes when the adjustments are
carried out. So it is not necessary to check the cylinder pressure after the
adjustment.
Electronic cylinder
lubricator
The
concept of the new electronic cylinder lubricator is illustrated in Fig. 14. A
pump station delivers lube oil to the lubricators at 45 bar pressure. The
lubricators have a small piston for each lube oil quill in the cylinder liner,
and the power for injecting the oil comes from the 45 bar system pressure,
acting on a larger common driving piston as shown in Fig. 15. Thus, the driving
side is a conventional common rail system, whereas the injection side is a
high-pressure positive displacement system, thus giving equal amounts of lube
oil to each quill and the best possible safety margin against clogging of single
lube oil quills.
Fig.
14: System design of the electronic cylinder lubricator
Fig. 15: Cylinder lubricator
unit, controlled by the computer and driven by 45 bar lube oil pressure
For
the large bore engines, each cylinder has two lubricators (each serving half of
the lube oil quills) and an accumulator, while the small bore engines (with
fewer lube oil quills per cylinder) are served by one lubricator per cylinder.
The pump station includes two pumps (one operating, the other on stand-by with
automatic start up), a filter and coolers.
The
lubricator can be delivered for our conventional engines in which case it is
controlled by a separate computer unit
comprising a main computer, controlling the normal operation, a switchover unit
and a (simple) back-up unit. A shaft encoder (which can be shared with a PMI
system) supplies the necessary timing
signal in that case. When used on ‘Intelligent Engines’, these functions are
integrated in the engine control computers and their shaft encoders.
The
lubrication concept is intermittent lubrication – a relatively large amount of
lube oil is injected for every four (or five or six, etc.) revolutions, the
actual sequence being determined by the desired dosage in g/bhph. The injection
timing is controlled precisely and – by virtue of the high delivery pressure –
the lube oil is injected exactly when the piston ring pack is passing the lube
oil quills, thus ensuring the best possible utilisation of the costly lube oil.
This is illustrated in Fig. 16.
Fig. 16: Pressure measured in
cylinder lubricating oil quills, and timing of lube oil injection
The
control computers have passed the necessary tests (E10), and the final approval
by a number of Classification Societies took place in Copenhagen in April 2000,
paving the way for largescale commercial deliveries. Production of the
electronic hardware has started and the first commercial units are in service
on K90MC/MC-C/MC-S and S90MC-C engines.
Prior
to that, the system was tested in operation on a 7S35MC for more than two years
with good results, and tests on a cylinder of a K90MC engine over some 12,000
service hours have given very satisfactory results, with low lube oil dosage
(for more details, please see [4]).
Starting
air system. On the Intelligent Engine, the pneumatic control system for the
starting air valves has been replaced by an electronically controlled system
with solenoid valves on the starting air valves, offering greater freedom and
more precise control. The ‘slow turning’ function is maintained.
Advantages of the
Intelligent Engine Concept
The
electronic control of the fuel injection system and the exhaust valve operation
means a number of advantages that are briefly listed below, categorized in
three main groups.
Reduced fuel
consumption:
•
fuel injection characteristics can be optimised at many different load
conditions whereas a conventional engine
is optimised for the guarantee load, typically at 90-100% MCR
•
constant pmax in the upper load range can be achieved by a combination of fuel
injection timing and variation of the compression ratio (the latter by varying
the closing of the exhaust valve). As a result, the max. pressure can be kept
constant over a wider load range without overloading the engine, leading to
significant SFOC reductions at part load.
•
the on-line monitoring of the cylinder process ensures that the load
distribution among the cylinders and the individual cylinder’s firing pressure
can be kept up to ‘as new’ standard, maintaining the ‘as new’ performance over
the lifetime of the engine.
Operational safety and
flexibility:
•
the engine’s crash stop and reverse running performance is improved because the
timing of exhaust valves and fuel injection can be optimal for these situations
too
•
‘engine braking’ may be obtained, reducing the stopping distance of the vessel
•
faster acceleration of the engine because the scavenge air pressure can be
increased faster than normal by opening the exhaust valve earlier during
acceleration
•
dead slow running is improved significantly: the minimum r/min is significantly
lower than for a conventional engine, dead slow running is much more regular,
and combustion is improved thanks to the electronic control of fuel injection
•
the electronic monitoring of the engine (based on our CoCoS-EDS system)
identifies running conditions which
could lead to performance problems. Damage due to poor-ignition-quality fuel
can be prevented by fuel injection control (pre-injection)
•the
engine control system includes our on-line OPS-feature: Overload Protection
System, which ensures that the engine complies with the load-diagram and is not
overloaded (as is often seen in shallow waters and with ‘heavy propeller’
operation)
•
maintenance costs will be lower (and maintenance easier) as a result of the
protection against general overloading as well as overloading of single
cylinders, and the ‘as new’ running conditions for the engine, which is further
enhanced by the ability of the engine diagnosis system to give early warning of faults, thus enabling proper
countermeasures to be taken in due time.
Flexibility regarding
exhaust gas emissions:
•
the engine can change over to various ‘low emission modes’ where its NOx
exhaust emission can be reduced below the IMO limits if desirable due to
‘local’ emission regulations
•
by suitable selection of operating modes, the vessels may sail with lower
exhaust gas emission within ‘special areas’ where this may be required (or be
economical due to special harbour fee schemes) without having negative effects
on the SFC outside such special areas.
Service Experience with
the Intelligent Engine
The
world’s first Intelligent Engine in service as the main propulsion engine for a
merchant vessel is the 6L60MC of the chemical product carrier M/T Bow Cecil,
which was delivered in October 1998 to the Norwegian owner Odfjell ASA by the
Kværner Florø Yard in Norway.
Design of IE systems
for M/T Bow Cecil
The
engine was prepared for the IE systems during its production. The mechanical/
hydraulic components of the IE systems were fitted to the engine during its
installation in the vessel at the yard. These systems are installed on the
upper platform of the engine, in parallel with the conventional camshaft, as
shown in Fig. 17.
Fig.
17: Installation of the IE fuel injection and exhaust valve control systems in
parallel with
the
conventional camshaft of the 6L60MC main engine of M/T Bow Cecil
With
this set-up, it is possible to change over completely from the conventional
system to the IE system, or vice versa, within some three hours, so there is
full redundancy. Fig. 18 is a photo taken at the yard in 1998, showing the
installation of the IE systems on the upper platform of the engine.
The
power for operating the fuel injection system and the exhaust valves is
supplied by a hydraulic powerpack. This comprises high-pressure axial piston
umps, driven by the engine (see Fig. 19), together with electrically driven
pumps, supplying oil pressure prior to starting the engine and controlling the
oil flow during its operation. The working medium is fine filtered engine
system oil, as described in detail below.
Service experience with
IE systems on M/T Bow Cecil
The
ordinary camshaft system was used on the sea trial in accordance with the
original contract between the parties, and it has also been used during the
first operating period of the vessel. During this time, the auxiliary systems
have been put in operation and tested thoroughly. The following has been
experienced with these systems prior to the operation as a complete
‘Intelligent Engine’:
Fig. 18: Installation
of IE system on the upper platfrom of the 6L60MC main engine of M/T Bow Cecil
Fig. 19: Engine driven
high-pressure pumps on the front end of the 6L60MC engine
Hydraulic
oil conditioning system. The power medium employed for operating the fuel
injection pumps and the exhaust valves is fine-filtered system oil from the
engine, thus avoiding a separate hydraulic oil system with tanks, pumps,
coolers, etc. The driving system utilises lube oil at a moderate working
pressure (160–200 bar), but even so it is essential for ensuring a long
lifetime of such hydraulic systems that the oil is clean, which requires ISO
x/16/13.
However,
the requirements for the engine system oil are not that strict – nor are they
needed for the engine itself; therefore, the oil for the IE systems requires
extra filtration. For this purpose we use an automatic 6-micron filter located
in the supply line to the IE system from the main lube oil pipe of the engine.
From a system point of view, this acts as by-pass filtration and thus, over
time, will fine-filter the whole oil charge of the engine – obviously with the
risk of clogging the filter.
Before
deciding to use this system, we had tested it on our 4T50MX research engine
with good results, confirming that filter clogging was not a problem and that
the higher inlet pressure supplied to the hydraulic power supply unit
(engine-driven axial piston pumps) was indeed an advantage for these pumps.
Subsequently,
the filter system was fitted to a sister vessel to M/T Bow Cecil and
service tested over a period of one year. The results were very satisfactory,
again confirming that filter clogging was not a problem and that also the whole
oil charge of the engine became significantly cleaner than before – an added
benefit for the engine.
The fine-filtering system has also been
in operation on M/T Bow Cecil ever since the sea trial. The
‘commissioning’ of the filter during the sea trial is illustrated in Fig. 20.
The first operating hours during a sea trial must be expected to deliver rather
high amounts of particles (i.e. a high filter load). However, it can be seen that
back-flushing of the filter is not triggered by the permissible pressure drop
across the filter (max. 0.6 bar) being exceeded, but only by the timer, which
is set to backflush every hour. The subsequent service experience with the
system has been very satisfactory – the only problem encountered was a ‘cold
soldering’ on the print card for the filter control, which has been rectified
by the supplier.
Fig. 20: Commissioning of
fine-filter during the sea trial of M/T Bow Cecil
On-line
cylinder pressure measuring system PMI, and CoCoS-EDS.
These two systems were installed on the engine
in August 1999 and are now being used by the crew as normal tools for
monitoring the engine. After some minor teething troubles onboard, the PMI
system is working stable and reliably, providing on-line data on the working of
the cylinders to the CoCoS Engine Diagnosis System (EDS).
Electronic hardware and software.
The development of the electronic control
systems for fuel injection and exhaust valve actuation was delayed due to the
complexity of the software. The hardware has passed the required test (E10).
Software approval is a two-step procedure: first, a SW development audit must
be performed by the Classification Society in question (Det Norske Veritas).
This has been done, and we have been approved for developing such software. The
second step comprises a demonstration (on the 4T50MX research engine) of the
functionality of the SW in the actual HW, for the purpose of proving that the
complete system works as described in the design specification. This test was
performed to the full satisfaction of DNV in September 2000.
The Mode Selection
screen of the HMI (Human Machine Interface) is shown in Fig. 21. Using this,
the operator has the possibility to switch between the operating modes for the
engine (‘Fuel Economy’ and ‘Emission Control’), as well as to switch between
governor control modes such as ‘Constant Speed’ and ‘Constant Torque’.
An
overview of the engine status is available from the ‘Main Status Display’, as
can be seen in Fig. 22. This shows (at the top) the actual mode for the engine,
the governor and the hydraulic power supply system. It indicates from where
control is taking place (the bridge in the case shown here) together with index
status and the actual propeller pitch for the CP propeller.
Control
of the hydraulic power supply. The control software for the hydraulic power
supply (engine and electrically driven hydraulic pumps) has been finalized and
tested. The control system was successfully installed and tested on board M/T
Bow Cecil in April 2000.
Full
scale IE service tests on M/T Bow Cecil. After completion of the
demonstration of system functionality for DNV, the next step was to start
actual operation with the computer controlled fuel injection and exhaust valve
actuation systems – the world’s first full scale ‘Intelligent’ marine engine in
service.
In
consideration of the vessel’s service schedule, it was found feasible to start
this test with a ‘quay trial’ outside Hamburg, Germany, on 1st-2nd October
2000. During this trial, all systems were tested with very satisfactory results
– including perfect dead slow operation at 15 r/min.
The
final step before the vessel resumed its schedule – now as an Intelligent
Engine, i.e. without a camshaft – was a sea trial wich was carried out in the
presence of surveyors from Det Norske Veritas in order to have the final
approval from DNV and to maintain the vessel´s certificate.
This
sea trial was carried out off Borneo on 7th and 8th November 2000. The final
approval document from DNV states: ‘All
tests were passed and it is judged that the engine and associated systems
perform equally as good or better with the Intelligent Engine system in
operation as with the traditional camshaft system’.
Thus,
the end of the successful sea trial marked the beginning of the long-term
service test which will be conducted over a period of some 10,000 operating
hours to confirm the efficient and reliable operation of both the IE systems
and the engine proper.
Fig.
21: Mode Selection Display
Fig.
22: Main Status Display
Commercialization
of the IE Concept
In
1999, two V-Max class ULCCs (Fig. 23)
were ordered at Hyundai Heavy Industries in Korea for delivery in first-half of
2001, each with two 7S60ME-C engines, the ‘Intelligent Engine’ version of the
well-established 7S60MC-C engine.
As
a result of the previously mentioned delays in the development of the control
software, and in order to ensure that the vessels are delivered on time, it has
been agreed to make provision for conventional operation during the initial
service period of the two vessels. The engines will be delivered prepared for
later conversion to the 7S60ME-C version and will have the PMI on-line cylinder
pressure measuring system, the CoCoS-EDS engine diagnosis systems, the
CoCoS-MPS maintenance planning system and the electronic cylinder lubrication
system in operation from the outset.
This
will allow time to gain appropriate service experience with M/T Bow Cecil.
Subsequently, the engines will be converted to proper 7S60ME-C ‘Intelligent’ engines
during the scheduled docking of the vessels. At that time, the conventional
camshaft system will be removed and replaced by the IEsystems, which will
utilise the existing camshaft housing as oil pan and foundation.
Chapter-3
The First
Commercial ME Engine
After
a highly successful experience with the prototype 6L60MC/ME engine, Odfjell
ASA, Norway, commissioned the World’s first dedicated ME engine, a 7S50ME-C,
from MAN B&W Diesel’s Frederikshavn Works.
This
particular engine will be installed in to a new building, KF 144. It is
destined to power a chemical carrier being built by the Kleven Florø yard,
Norway. MAN B&W Diesel are also supplying the GenSets and Controllable
Pitch Propeller systems for the ship.
Unlike
the prototype, this engine was designed and built without a camshaft –making it
a truly cam-less engine. The functions of the camshaft have now been taken over
by a fully integrated and computer controlled electro-hydraulic Engine Control
System (ECS).
The
ECS system controls the timing of the fuel injection through close monitoring
of the crankshaft position via a tacho system, which is far more accurate and
responsive than any mechanical method of control. This results in savings in
fuel and lube oil consumption and at the same time gives greater manoeuvring
control.
In
addition to this highly efficient and controllable system, other MAN B&W
Diesel innovations have also been integrated into this electronic engine. The
Alpha Lubricator ACC has also been specified in addition to the CoCoS-EDS – the
very successful engine monitoring and diagnostic system from MAN B&W
Diesel.
The
most visually different aspect of this engine, when compared to the older
designs, is the removal of the timing chains. This change, in combination with
the removal of the camshaft, has resulted in weight savings. In addition to
this being a compact engine, hence the designation ME-C, the removal of the
chains also gives the opportunity to further reduce the overall length of the
engine.
Fig.
1: Completed – the first commercial ME engine
What is a cam-less
engine
In
this engine, the camshaft functions are replaced by an electronically
controlled set of actuators. These actuators control the Starting air valves,
Start and Reversing sequences, Governor function, Auxiliary blowers,
Electronically Profiled Injection (EPIC) and Exhaust valve actuation.
This
is done with far greater precision than camshaft-controlled engines. The
exhaust valves, as on the MCengines, are opened hydraulically and closed by an
‘air spring’. The actuator is hydraulically driven by pressurized control oil
via an on/off type valve.
The
Starting air distributor has now been replaced by electronically controlled
on/off valve which, in conjunction with the ECU and the CCU, control the
Starting air valves.
The
hydraulic power is provided by the Hydraulic Power Supply units placed at the
aft end of the engine. The cam-less system, being electronically controlled, is
fully integrated with other MAN B&W Diesel developments such as more
efficient fuel and lube oil injection and the CoCoS engine diagnostic platform.
This control makes the overall optimisation of each system even more effective
and reliable.
The
ECS can fully control and optimize the combustion process at any load by electronically
controlling the valves according to the crankshaft position.
Electronic Control
The
engine is controlled and monitored via the ECS. This platform encompasses
several integrated units: the Engine Interface Control Units (EICU), Engine
Control Units (ECU), Auxiliary Control Units (ACU) and Cylinder Control Units
(CCU).
Fig. 3: Cross section – the first
commercial ME engine
The EICUs handle the
interface to external systems.
•
The ECUs perform engine control functions: engine speed, running modes and
start sequence.
•
The ACUs control the hydraulic power supply and auxiliary blower pumps.
•
The CCUs control fuel injection, valve actuators and starting air valves.
Reductions in the
Specific Fuel Oil Consumption (SFOC) are achieved at part load. This is due to
the maximum pressure being maintained over a wider load range and without
overloading the engine.
Fig. 2: Hydraulic power supply
filtration unit
Alpha Lubricator ACC
Alpha
ACC allows the cylinder oil dosage (g/bhph) to be controlled in such a way that
it is proportional to the amount of sulphur (g/bhph) entering the cylinder with
the fuel.
This
is achieved by making the cylinder oil dosage proportional to the sulphur
percentage in the fuel and to the engine load (fuel amount).
The
main element of the cylinder liner wear is of a corrosive nature, and the
amount of neutralising alkalinic components needed in the cylinder will
therefore be proportional to the amount of sulphur (which generates sulphurous
acids) entering the cylinders.
A
minimum cylinder oil dosage is set in order to satisfy other requirements of a
lubricant, such as providing an adequate oil film and detergency properties.
Fig.
4: Top of engine
Fig.
5: Tacho system and hydraulic power supply system
Computer Controlled Surveillance
System (CoCoS)
The
CoCoS system has been specified as the engine monitoring, diagnostic and
maintenance overview system on this engine. It is a comprehensive collection of
MAN B&W Diesel-developed software, which is designed to detect various data,
determined through the alarm system as well as other sensors in order to keep
the engine working in its optimum state.
The
CoCoS system’s four major programme groups consist of: the Engine Diagnostic
System (EDS), a Maintenance Planning System (MPS), a Stock Handling and Spare
Parts Ordering (SPO) facility and
the Spare Parts Catalogue (SPC).
The
EDS continually monitors all stored operating parameters for the entire
lifetime of the engine, and provides a warning to the attendant staff if it
suspects a problem is developing. If a problem is likely to occur, the
appropriate work can be scheduled through the MPS, perhaps to coincide with
other planned maintenance work. The MPS normally shows scheduled maintenance
work together with timing instructions, list of required tools, spare parts and
manpower requirements.
While
scheduling maintenance, the SPO system automatically checks whether the spare
parts are available (while allowing for a minimum and safety reserve), and the
SPC gives the opportunity for the staff to display them (either in graphical or
textual form).
The
aim of the system is to prevent longer than necessary off-service repair time
by increasing the engine’s availability and reliability, thus reducing
operational costs. Additional savings can also be achieved through the
appropriate scheduling of maintenance and spare parts ordering.
PMI System
The PMI system is a
computerised tool for evaluation cylinder pressures in MAN B&W Diesel
engines. It consists of a hand held transducer and control unit, which
interfaces with a PC.
A
single operator can collect and display a complete set of measurements in less
than fifteen minutes. It uses a high performance piezo-electric pressure
transducer and an advanced crankshaft angle trigger system for determining the
TDC of each cylinder to reliably and precisely measure cylinder pressures.
The
cylinder pressure data is presented as easy-to-interpret measurement curves on
the PC as well as in tabular form. By calculating the max. pressure deviation
of each cylinder and computing index settings for balanced output from all
cylinders, the engine output can be adjusted for enhanced performance.
The
system automatically calculates effective power, mean indicated pressure pi ,
and gives proposals for fuel pump index adjustments.
Alphatronic 2000
Control System
This
electronic propulsion control system for ships with CP propellers enables the
navigator to manoeuvre the ship from the bridge. This can be done without
consideration for engine load conditions as the system automatically enacts an
overload protection. The propulsion control can be transferred at any time to
other control areas such as the bridge wing or control room panel. A separate
emergency back-up system, as required by the major classification societies,
maintains a pre-set engine speed and propeller pitch, and is physically
integrated into the control panel.
ME ENGINE ADVANTAGES
Variable
electronically-controlled timing of fuel injection and exhaust valves for lower
specific fuel consumption and better performance parameters
·
Lower
rpm possible for manoeuvring
·
Better
astern and crash stop performance
·
Improved
emissions characteristics, such as lower NOx and smoke values at any load
·
Equalized
thermal load in and between cylinders minimizing the risk of premature need for
overhaul
·
System
incorporating performance monitoring to promote longer times between overhauls.
CHAPTER-4
SERVICE
EXPERIENCE 2008, MAN B&W ENGINES ME/ME-C AND MC/MC-C ENGINE SERIES
The number of electronically controlled
engines in service continues to grow
and, at the time of writing, more than 500 engines are on order or in
service.
At the end of 2007, the first S40ME-B
engine was prototype-tested at STX in Korea, Fig. 8.1. These tests mark the
beginning of an era where the full potential of the electronic fuel injection with “rate shaping” (or “injection
profiling”) is utilised on
production engines giving a very
attractive NOx/SFOC relationship.
Fig.
8.1: 6S40ME-B engine
At the beginning of January 2008, the
first four LNG carriers with 2 x 6S70ME-C engines (Fig. 8.2) were in service.
During 2008, this number will increase to 20 vessels.In addition to the service
experience update for the ME/ME-C engine
series, this paper will describe the recent service experience relating to conventional
mechanical issues of MAN B&W twostroke engines. The condition-based
overhaul (CBO) concept and an update on monitoring systems will also be given.
Fig. 8.2: LNG carrier with 2 x 6S70ME-C
engines
Update
on Service Experience, ME/ME-C Engine Series
At the end of 2007, 1 0 ME/ME-C engines
were in service. The reporting will be divided into the various
sub-systems of the ME/ME-C engines.
These are the hydraulic cylinder unit
(HCU), the multi purpose controller
(MPC), the hydraulic power supply (HPS)
and the servo oil system.
Hydraulic
cylinder unit (HCU)
For the HCU, we will concentrate on two
main topics, i.e. the ME control valves and the exhaust valve actuator system.
ME
control valves
ELVA/ELFI valves(Curtiss Wright supply)
ELVA/ELFI configuration (one control
valve
for exhaust valve actuation and another control valve for fuel injection
control) are in service on 20 plants. For the on/off ELVA valve, a modified
high-response valve is undergoing service testing. When this service testing is
concluded, the 20 plants will be updated
and service issues with the ELVA/ELFI configuration will then be solved.
FIVA Valve (Curtiss Wright version) The
feedback loop of the FIVA valve position control, Fig. 8. , has caused untimed injection and untimed exhaust valve
operation owing to various reasons.
These reasons are related to the FIVA valve itself in some cases, and
in other cases to the part of the
feedback loop in the multi purpose controller
(MPC), see multi purpose controller chapter.
In the original version, the electronics
on the printed circuit board (PCB) in the Curtiss Wright FIVA valve showed
thermal instability causing untimed actuation of the valve. The reason was an
analogue voltage regulator generating
Fig. 8.3: FIVA valve position control
an
excessive amount of heat raising the temperature by 5ºC on the PCB. In some
cases, this caused a temperature
shutdown of the LVDT converter in the feedback loop, resulting in the abovedescribed unstable function of the FIVA valve. The
solution was to exchange the analogue
voltage regulator with a switch mode regulator, Fig. 8.4. Hereby, the temperature of the PCB was lowered by
approx. 5ºC.
Fig. 8.4: FIVA
valve feedback failure: exchange of analogue voltage regulator with switch mode
voltage regulator
Furthermore,
in order to safeguard against untimed movement of the FIVA main slide due to an
erroneous feedback signal, improved supervision is introduced by new software, see
multi purpose controller chapter. In 2007, we experienced a cylinder cover
lift
twice on testbed with 6S70ME-C engines. The reason for these incidents was
untimed movement of the FIVA valve main slide owing to a drilling chip left
inside the main slide during production, Fig. 8.5. After discovering this
production mistake, we have, together with the sub-suppliers,
cleaned/re-machined approx. 500 main slides to avoid loose drilling chips
inside the FIVA valves.
Fig. 8.5: CWAT FIVA valve: chips found
in main slide
Fig. 8.6: CWAT FIVA valve: Movement of
pilot valve and main slide
Fig. 8.6 gives an explanation of what
happens if a loose drilling chip is stuck between
the
pilot slide and the main slide.
Fig. 8.6 (left hand side) shows the
valve in balance. This means that the constant pressure on the bottom of the
main slide is balanced by a pressure creating a similar force in downward
direction, thus keeping the slide in neutral (“zero”) position.In order to open
the exhaust valve or to stop fuel injection (Fig. 8.6, centre), the pilot slide
should be moved downward, thereby increasing the pressure on the top of the
main slide and moving the main slide downward. This will result in exhaust
valve opening or stop of fuel injection.
When the pilot slide is moved
upward(Fig. 8.6, right hand side), pressure on the top of the main slide is
decreasing and the main slide is moved upward enabling closure of the exhaust
valve or fuel injection. If a drilling
chip is stuck in between the pilot and the main slide when the exhaust valve is closing, there is a
risk of fuel injection just after closing
of the exhaust valve. This will create an excessive pressure build-up in
the combustion chamber and a risk of
cylinder cover lifting. This was the cause of the two cylinder cover
lifts on the 6S70ME-C engines on testbed
in 2007.
FIVA Valve (MAN B&W version) During
2007, the first vessels with MAN B&W FIVA valves controlling ME engines
went into service.
The MAN B&W FIVA valve can be seen
in Fig. 8.7. It consists of a valve main
body
on which the Parker pilot valve and the H. F. Jensen feedback sensor are
mounted. For the Parker valve, we have seen a number of units failing because
of:
Fig. 8.8a: Broken bushing, b: Damaged
wire strip, c: Parker valve
A: Broken bushing
for the pilot slide,Fig. 8.8a. This item was rectified during the prototype
testing period
B: Earthing failure owing to damage ofa
flexible wire strip inside the valve, Fig. 8.8b
C: Malfunction owing to failing
operational amplifier, Fig. 8.8c
Fig. 8.9a: Redesign of rod for sensor in
H.F. Jensen feedback sensor
A:
Breakage of the rod in the sensor. The rod in the sensor has been redesigned,
Fig. 8.9a
B:
Broken or loose connection between the print board and the external connector
(type: Canon),Fig. 8.9b. Redesign of the connection has solved the problem. In
parallel with solving teething problems with the Parker pilot valve and the H.
F. Jensen feedback sensor, other makes of pilot valves and feedback sensors
are being tested. Parker valves with certain serial numbers have been replaced in service.
Fig. 8.9b: Connector breakdown,
H.F.Jensen feedback senso
With respect to the H. F. Jensen
feedback sensors, we have experienced two different problems:
FIVA Valve (Bosch Rexroth version)
Service tests of the Bosch Rexroth FIVA valve, Fig. 8.10, on a 12K98ME have been concluded successfully. Bosch
Rexroth FIVA valves are now the third
alternative for control valves for the present ME engine series.
Fig. 8.10: Bosch Rexroth FIVA
Cavitation
in the exhaust valve actuation system
Cavitation in the exhaust valve
actuation system has been seen in the exhaust valve top part, Fig. 8.11a, as
well as in the exhaust actuator top cover, Fig. 8.11b. Furthermore, damage to
the oil inlet non-return valves on the actuator top cover indicates excessive
pressure fluctuations in the exhaust valve actuation system. An orifice in the
drain line from the FIVA valve, Fig. 8.12, has been introduced to reduce the
acceleration of the actuator piston and hereby eliminating cavitation on the
actuation side At the time of writing, we are monitoring cavitation development
after the introduction of the orifice in the FIVA return line. However, in
parallel, we are testing further modifications:
A:
Reduced braking of the exhaust valve by introduction of an orifice (small hole)
in the damper piston, Fig. 8.1 .
B:
Low-pressure oil supply in the top of the exhaust valve, Fig. 8.1 . It is
considered to move one of the lowpressure supplies on the actuator, Fig. 8.14,
to the top of the exhaust valve.
Fig. 8.11a: Cavitation in exhaust valve
top part Fig. 8.11b: Cavitation in
exhaust actuator top cover
Introduction
of ring orifice corresponding to a 20 mm orifice in the hydraulic system for
exhaust valve on K98ME-C
Fig. 8.12: Orifice in the drain line
from the FIVA valve
Fig. 8.13: Exhaust actuation system,
scheduled test rig tests
Fig. 8.14: Non-return valves in low
pressure supply lines
Multi
purpose controller (MPC)
In
2007, we experienced one severe case of cylinder cover lift on a 6S60ME-C
engine in service. After investigations into the parts involved on the cylinder
unit in question, it was concluded that
the reason was an error in the feedback loop for the FIVA control, Fig.
8. . However, in this case the error was in the MPC part of the feedback loop.
A loose/broken connection in the feedback circuit of the MPC was found during
the investigation, see Fig. 8.15. Countermeasures in this relation were divided
into three parts.
Fig. 8.15: Broken/loose connection in
the MPC
Firstly, a circular letter warning
against a specific alarm sequence was issued in order to exchange MPCs with
similar potential defects. This circular letter was sent to all operators of ME
engines.
Secondly,
it was concluded from tests that the reason why the error in the feedback loop
of the MPC caused an untimed injection was that the feedback signal froze on a
low value. When the closed loop control tried to rectify the position of the main
slide in the FIVA valve, it moved the main slide towards fuel injection and
continued to do so until injection (untimed) was accomplished. This was done
because of the frozen low-value feedback signal.
Based
on this knowledge, it was decided to invert the feedback signal, Fig. 8.16. By
doing this, a frozen low value feedback signal will result in a FIVA main slide
movement towards untimed opening of the exhaust valve. This is considered to be
“failing into safe
mode”.
Fig. 8.16: FIVA valve flow area diagram
Thirdly,
in order to safeguard further against similar incidents, a new software version
with closer supervision of the feedback signal [1] and additional supervision
of the fuel plunger movement [2] has been introduced, Fig. 8.17. Control
processes including the supervisions [1] and [2] are seen in Fig. 8.18.
All
ME engines in service have been or will be updated with the above
ountermeasures.
Fig.
8.17: FIVA valve position control
Fig. 8.18: Crankshaft related control
processes
Hydraulic
power supply (HPS)
In 2006, we experienced a breakdown of
the bearings in an HPS on a 12K98ME engine. A design review was initiated and
modifications were implemented, both for new engines and for engines in
service. After this incident we have not seen further incidents
relating
to the HPS bearing/bushing design on the ME engines.
For a series of the first S70ME-C
plants, the chain wheel and gear wheel assembly on the HPS common shaft has
shown to be under-dimensioned, Fig. 8.19. An upgrade of the bolt connections
has been introduced on the concerned vessels in service.
Servo
oil system
For the present ME engines, two
alternative servo oil systems are available:
A: A standard
system where engine system oil is processed through a 6-10 µm full-flow fine
filter and then led into the hydraulic pumps of the HPS.
B: An optional
system where a separate servo oil system with a separate tank system is used,
Fig. 8.20. The oil is cleaned by a cleaning unit (filter or purifier) mounted
on the separate oil tank.
During 2007, we experienced one case of
severe contamination of the servo oil system owing to a breakdown of the ship
side transfer pumps. This happened on an installation equipped with a separate
servo oil system (B).
Fig.
8.19: S70ME-C assembly of shaft for hydraulic pump
Fig.
8.20: Separate hydraulic oil system, initial version
Apparently,
the screw type pumps produced the contaminating products rather quickly and,
therefore, a lot of debris ended up inside the ME control valves, see Fig.
8.21.
After
this incident, we have revised our specification for the separate servo oil
system, Fig. 8.22. The important change is that a 6 µm full-flow fine filter
has been introduced, also on the separate servo oil system.
For
engines in service with a separate servo oil system, we recommend to add a
‘‘water-in-the-oil monitor’’, connect
the oil temperature measurement to the alarm system and install a metal
detector just before the hydraulic power supply.
Fig.
8.22: Separate hydraulic oil system, updated version
Update
on Service Experience, MC/MC-C Engine Series
In the following, we will describe the
recent service experience on the MC/ MC-C engine series, with focus on
condition based overhaul (CBO) and update on monitoring systems. CBO is of
couse also relevant and possible for ME/ME-C engines.
Condition
based overhaul (CBO) of pistons
The experience with our engines with the
latest updated combustion chamber design, i.e. with Oros shape and the latest piston ring design, slide fuel
valves and optimised temperature levels, counts more than seven years of
operation. Against this background, we have gained valuable knowledge about
the
need for piston overhauls compared with earlier experience.
The “Guiding Overhaul Interval” for
pistons, previously set to 12-16,000 hours, appears to have been set too
conservatively. Normally, the need for piston overhaul does not arise until
much later, and extensions up to 2,000 hours are possible. However, the fact is
that the scatter is large, and many factors are
This calls for a CBO strategy, the
objective being to obtain the highest number possible of safe running hours.
Preferably, overhauling should only be carried out when necessary.
The most important factor in a CBO
strategy is the evaluation of the actual condition, by means of regular
scavenge port inspections and logging of wear and hot corrosion. All the
decisive factors for piston overhaul can
be checked via inspections through the scavenge air ports.
The most important factors for piston
overhauls are fig 8.23:
•
Piston ring wear
• Max. amount of
hot corrosion of piston top allowed on the centre part (where it is normally
highest)is 9/12/15 mm on, respectively, 80/90/98-bore engines
• Ring groove
clearance Max. recommended clearance is 1.0 mm on the 80 and 90-bore
engines,and 1.1 mm on 98-bore engines
•
Sticking, broken or collapsed piston rings or leaking pistons
•
Macro-seizures on piston ring running surfaces.
Fig.
8.23: K98 example. The four (4) important factors for piston overhaul
Inspection and logging of the actual
cylinder condition and wear should be performed regularly to become familiar
with the wear-and-tear development in the cylinder. At the beginning, intervals
should be short, e.g. every second to third week. The intervals can be
prolonged as confidence builds up.
The
following factors should be measured and recorded:
•Top piston ring wear, defined by
measuring the remaining depth of the CL grooves.
•Ring groove clearances, measured with a
feeler gauge.
•Estimated
piston burnings on large bore engines, measured by means of a template via the
scavenge ports.
Our
standard sheets “Cylinder Condition Report” and “Inspection through Scavenge
Ports” can be used, forming the ideal documentation for later review and for
making trend curves for future wear forecasts, Fig. 8.24.
Fig.
8.24: 10K98MC-C, unit no. 7, at 23,500 hours without overhaul. The condition
does not call for piston overhaul
The
running surfaces of the piston rings are the best indicators of the cylinder
condition in general. If the ring surfaces appear to be in good condition and
free from scratches, micro or macroseizures, the liner will also be in good
condition, Figs. 8.25-8. 0.
Figs.
8.25-8.27 describe conditions of the new cermet coated ring packages with
alu-coat running-in. Figs. 8.28-8. 0 describe the conditions of the alu-coated
ring packages.
Conversely,
if the liner appears damaged by active seizures (if the wave-cut pattern has disappeared on the lower cylinder part visible through the ports), the
rings will also be affected, and most likely the unit has to be overhauled.
As mentioned above, the wear on the top
piston rings can be determined by measuring the remaining depth of the CL grooves using a Vernier gauge, but the wear
can also be estimated visually simply by
checking the size of the remaining rounding on the upper and lower edges of the
running surfaces.
From new, the rounding has a radius
of 2 mm on 80/90/98-bore engines.
Thus, a simple visual inspection through the scavenge ports confirming that
the rounding is still visible or partly
visible is an indication that the wear limit has not been reached, and
that many more hours are left before piston
overhaul is necessary. For further information, we refer to our Service
Letter SL07-48 .
ce Experience
ME/M
E Fig. 8.31: W-seat and DuraSpindle combination CBO of exhaust
valves
Fig. 8.32: W-seat in combination with nimonic
spindle and DuraSpindle
For the exhaust valve, the use of Wseat,
Fig. 8. 31, and either nimonic valve spindle or DuraSpindle has improved the overhaul intervals to longer than 2,000 hours. Fig. 8. 32 shows examples of an
excellent condition without overhaul
with combinations of a W-seat/ nimonic spindle and a W-seat/DuraSpindle
achieved
on an S60MC engine after 25,500 hours
and ,900 hours, respectively.
Fig. 8.33:
Controlled oil level (COL) design
Clean
lubricated spindle guide and a sealing ring with a wear profile which well
indicate running up to 30,000- 35,000 hours.
7K98MC:
COL test unit, inspection after running hours 20,468 hours
Fig. 8.34: Inspection of COL design
For exhaust valve stem seal, the
socalled controlled oil Level (COL)
design, Fig. 8.33. , indicates that also tem seal overhaul intervals can be
extended to 30,000- 5,000 hours, based on results
from several test units on 98, 90 and 60
bore engines. This illustrated by Fig. 8. 34 showing an open-up
inspection on a K98.
CBO of bearings
Since the late 1990s, a
positive development with respect to main bearing damage has been seen. Despite the
heavy increase in the number of main bearings on MC/MC-C engines, Fig.
8. 35, the reported damage frequency remains very low, see Fig. 8.36.
Fig.
8.35: Main bearing population 1982-2008 divided into bearing types
For other bearing types (crosshead and crankpin bearings), the
damage frequency is also very low.
Fig. 8.36:
Thick shell main bearing damage statistic
However, in a few cases we
experienced severe damage causing
long-term offhire periods involving also costly repairs of the bedplate and/or the crankshaft. An example is shown in Fig. 8. 37. In this
case, the reason for the damage was
incorrect assembly after an open-up inspection of a main bearing after
sea trial.
Fig. 8.37: Main bearing damage on 6S70MC-C . 6S70MC-C on maiden voyage.*Continued running for 1½
hrs after 1st alarm, Main bearing
incorrectly assembled after inspection,3½ month repair
This sequence of events
following open-up inspections of
bearings is unfortunately being reported from time to time. We have therefore changed our
instruction material, not calling for
open-up inspection at regular intervals. In parallel, we have made so-called
bearing wear monitoring (BWM) systems a
standard on engines ordered in 2008. BWM
systems can also be retro- fitted on existing engines
In principle, the BWM system
monitors all the major bearings (main,
crankpin and crosshead) by measuring the distance to the bottom dead centre of
the crosshead, Fig. 8.38. The distance will decrease if wear occurs in one of
the major bearings, and the BWM system can then give an alarm.
Fig. 8.38: Bearing Wear Monitoring
(BWM), position of sensors
By
monitoring wear in the major bearings, condition based monitoring (CBO) of bearings is introduced, and regular open-up inspections can be limited to fewer than previously. Optimally, openup inspections should, if at all needed, only be carried out during dry-dockings or when indications (bearing metal in
bedplate
or BWM alarm) call for it.
This
revised strategy will further limit the
cases of severe bearing breakdowns.
Also
water in oil (WIO) monitoring systems have been added to the standard
instrumentation for newly ordered engines. This is especially important
in
relation to crosshead bearings with lead overlayer being sensitive towards corrosion due to a too high water content
in the system oil. For engines in
service, WIO is described in service letter SL05-460.
Time
between overhaul (TBO) for turbochargers
For
turbochargers, the major makers are now
promoting extended times between major overhauls
(Fig.
8. 39).This means that for new turbochargers, it will be realistic to require
major overhauls only during docking of the vessel. The overhaul intervals will
then in many cases be five years.
Fig. 8.39:
Modern turbocharger enabling more than 30,000 hours between major overhauls
CHAPTER-5
THE
SULZER RT-FLEX COMMON-RAIL SYSTEM DESCRIBED
Rather than ‘electronically controlled’,
it would be more accurate to describe Sulzer RT-flex engines as being computer
controlled. Th is is because in the RT-fl ex system, engine functions are fully
programmable, perhaps limited only by
the designers’ imagination and the laws of nature. Th e challenge is to use
this freedom to create practical benefi
ts for engine users.
The common-rail concept was adopted also
because it has the advantage that the functions of pumping and injection
control are separated. Th is allows a straightforward approach to the
mechanical and hydraulic aspects of the design, with a steady generation of
fuel oil supply at the desired pressure ready for injection. Th e common-rail concept also has
the unique advantage that it allows the fuel injection valves to be individually controlled. Usually there are
three fuel injection valves in each cylinder cover, and in the Sulzer RT-fl ex engines they are operated mostly in
unison but nder certain circumstances they are operated separately for optimum combustion performance.
The common-rail concept thus provides an
ideal basis for the application of a fully-integrated electronic control. Th e
combined fl exibilities of common rail and
electronic control provide improved low-speed operation, engine
acceleration, balance between cylinders, load
control, and longer times between overhauls. They also ensure better
combustion at all operating speeds and loads, giving benefi ts in lower fuel
consumption, lower exhaust emissions in
terms of both smokeless operation at all operating speeds and less NOX
emissions, and also a cleaner engine
internally with less deposits of combustion residues. Engine diagnostics are
built into the system, improving engine
monitoring, reliability and availability. As the common-rail system is built
specifi cally for reliable
Fig. 1: Principal elements of the common-rail system on a Sulzer RT-fl
ex engine. Note that there are variations on this arrangement in the various
RT-fl ex engine types depending upon the engine type and number of cylinders.
operation
on heavy fuel oil, it detracts nothing from the well-established economy of
low-speed marine diesel engines but rather
opens up new possibilities for even better economy, ease of operation,
reliability, times between overhauls and lower exhaust emissions.
It is more than ten years since
development of the Sulzer RT-fl ex common-rail system began and more than 20
years since the first tests were made with electronically-controlled fuel
injection in Winterthur, Switzerland.
The early camshaftless systems developed
for Sulzer engines relied on integral electronic control but used individual, hydraulically-operated fuel
injection pumps. However the change in injection concept from the individual,
hydraulically-operated fuel injection pumps
to a common-rail system in 1993 was made because the system with
individual pumps did not offer potential
for further technological development despite it having integral
electronic control. Electronic control was found to be insufficient by itself
and a new fuel injection concept was recognized as essential. Common rail was seen as the road
ahead and it is applied in Sulzer RT-fl ex engines.
Sulzer RT-flex engines are thus notably
different from other electronically-controlled low-speed diesel engines today
as Sulzer RT-flex engines are unique in combining the benefits of both
common-rail systems and electronic control.
Sulzer
RT-fl ex system
Sulzer
RT-fl ex engines are essentially standard Sulzer RTA low-speed two-stroke marine diesel
engines except that, instead of the usual camshaft and its gear drive, fuel injection
pumps, exhaust valve actuator pumps, reversing servomotors, and all their
related mechanical control gear, they are equipped with a common-rail system
for fuel injection and exhaust valve actuation, and full electronic control of
engine functions. There are four principal elements in the Sulzer RT-flex common-rail
system: the rail unit along the side of thecylinders, the supply unit on the
side of the engine, a filterunit for the servo oil, and the integrated
electronic control system, including the crank angle sensor.
The
RT-fl ex engines are thus equipped with common rail systems for:
• heated fuel oil at pressures up to
1000 bar,
• servo oil at pressures up to 200 bar,
• control oil at a constant pressure of
200 bar,
• engine starting air system.
RT-fl
ex Sizes
The hardware in the RT-fl ex system is
being developed in four principal sizes for the six engine types currently in the programme (see Table 1). The six RT-fl ex engine types
cover a power range of 8100 to 80,080 kW (11,000 to 108,920bhp).
This illustrates one of the advantages
of the commonrail system in that hardware is standardized for groups of engine
types, not just for the various cylinder numbers.
Fig. 2:
Schematic of the common-railsystems in Sulzer RT-fl ex engines
Supply
unit
Fuel and servo oil are supplied to the
common-rail system from the supply unit which is driven through gearing from the engine crankshaft.
In the first few RT-fl ex engines, the
supply unit is on the exhaust side of the engine so that it could be lower down without interfering with access to the
crankcase. However, for all subsequent engines, the location of the supply unit has since been standardized on the front of the engine (on the same side as the rail unit)
and at about mid height. This keeps the engine ‘footprint’ small so that the engines can be located far aft in
ships with fine after bodies.
The
supply unit is naturally at the location of the gear drive: at the driving end
for five- to seven-cylinder engines, and at the mid gear drive for greater
cylinder numbers.
Fig.
3: Supply unit for a Sulzer 12RT-fl ex96C engine with the fuel pumps in a
Vee-form
arrangement
on the left and servo oil pumps on the right-hand face of the central gear
drive. The fuel pumps all deliver into the collector seen above the fuel pumps.
The
supply unit has a rigid housing of GGG-grade nodular cast iron. The fuel supply
pumps are arranged on one side of the
drive gear and the hydraulic servo-oil pumps are on the other side. Th is pump
arrangement allows a very short, compact supply unit with reasonable
Fig.
4 above: Supply unit on a Sulzer 12RT-fl ex96C engine with the fuel pumps in a
Vee-form arrangement on the left and servo oil pumps on the right-hand face of
the
central
gear drive.
Fig.
5 right: Cutaway drawing of the fuel supply pump element for RT-fl ex96C
engines.
service
access. The numbers, size and arrangement of pumps are adapted to the engine
type and the number of engine cylinders.
For RT-fl ex Sizes I and IV, the supply
unit is equipped with between four and eight fuel supply pumps arranged in
Vee-form. The Size 0 supply unit, however, has just two or three supply pumps
in-line.
Two sizes of fuel pumps are employed for
all RT-fl ex engines, both based on the well-proven injection pumps used in
Sulzer Z-type medium-speed four-stroke engines though with some adaptations to
suit their function as supply pumps and to raise their volumetric efficiency up to a very high
degree. For Sizes 0 and I, the fuel pump elements are based on the injection
pumps of Sulzer ZA40S engines, while the Size IV pumps are based on the
injection pumps of the Sulzer ZA50S engine type.
The
fuel supply pumps are driven through a camshaft with three-lobe cams. This
camshaft cannot be compared with the traditional engine camshaft. It is very
short and
of
much smaller diameter, and is quite differently loaded.
There
is no sudden, jerk action as in fuel injection pumps but rather the pump
plungers have a steady reciprocating motion. With tri-lobe cams and the
speed-increasing gear drive, each fuel supply pump makes several strokes during
each crankshaft revolution. The result is a compact supply unit.
Two designs of camshaft are employed.
For Size I it is manufactured in one piece. For Size IV, the camshaft is
assembled from a straight shaft on to which the tri-lobe cams are hydraulically
press fi tted. This latter form of
Fig.
6: Close view of the fuel supply pumps in fi gure 4showing the regulating
linkage.
Fig.
7: Various RT-fl ex equipment on the half-platform of a 12RT-fl ex96C engine.
From left to right, these include (A) the local engine control panel, (B) the
automatic fi ne fi lter for servo and control oil, (C) the two
electrically-driven control oil pumps and (D) the supply unit.
construction
has been used for decades in Sulzer Z-type engines. It is extremely service
friendly and minimizes maintenance cost. Th e camshaft bearings have an
aluminium running layer.
The fuel delivery volume and rail
pressure are regulated according to engine requirements through suction control
with helix-controlled fi lling volume regulation of the fuel supply pumps.
Suction control was selected for its low
power consumption as no excess fuel is pressurised.
The roller guide pistons contain the
floating-bush bearings for the rollers as they are used on all Sulzer RTA- and Z-type engines. Owing to the
moderate accelerations given by the tri-lobe cam shape, the specific loads of
roller bearings and pins as well as the Hertzian pressure between cam and roller are less than
for the original pumps in ZA40S and ZA50S engines.
For
every individual fuel pump element of the supply unit, the roller can be lifted off the cam,
blocked and manually taken out of service in case of difficulties. The fuel
pumps deliver the pressurized fuel to an
adjacent collector from which two independent, doublewalled delivery pipes lead upwards to the fuel rail.
Each delivery pipe is dimensioned for full fuel flow.
The collector is equipped with a safety
relief valve set to 1250 bar. An equivalent arrangement of a collector and duplicated independent, double-walled
delivery pipes is
employed
for the servo oil supply.
Servo
oil
Servo oil is used for exhaust valve
actuation and control. It is supplied by a number of swashplate-type
axialpiston hydraulic pumps mounted on the supply unit.
The pumps are of standard proprietary
design and are driven at a suitable speed through a step-up gear. The working
pressure is controllable to allow the pump power consumption to be reduced. The
nominal operating pressure is up to 200 bar. The number and size of servo oil
pumps on the supply unit depend on the engine output or number of engine
cylinders. There are between three and six servo oil pumps.
The oil used in both the servo and
control oil systems is standard engine system lubricating oil, and is simply
taken from the delivery to the engine lubrication system. The oil is drawn
through a six-micron automatic selfcleaning
fine filter to minimise wear in the servo oil pumps and to prolong
component life.
After the fine filter, the oil flow is
divided, one branch to the servo oil pumps and the other to the control oil
pumps.
Control
oil
Control oil is supplied at a constant
200 bar pressure at all engine speeds by two electrically-driven oil
pumps, one active and the other on
standby. Each pump has its own pressure-regulating valve and safety valve
attached.
The control oil system involves only a
small flow quantity of the fine filtered oil. The control oil serves asthe
working medium for all rail valves of the injection control units (ICU). The
working pressure of the control oil is maintained constant to ensure precise
timing in the ICU. It is also used to
prime the servo oil rail at standstill
thereby enabling a rapid starting of the engine.
Fig. 8 above: Cylinder tops and rail unit of a
Sulzer 8RT-fl ex96C engine.
The electronic control units are mounted on the front below the rail unit.
Fig. 9 left: Three-dimensional drawing of the
inside of a rail unit for an RT-fl ex96C engine, showing the fuel rail (A), the control oil rail (B) and the
servo oil rail (C) with the control units for injection (D) and exhaust valve actuation (E) on top of their
respective rails. Other manifold pipes
are provided for oil return, fuel leakage return, and the system oil supply for the exhaust valve drives.
Fig.
10 below: Th e two sections of rail unit for a 12-cylinder RT-fl ex96C engine
during the course of assembly.
Fig. 11: Cylinder tops of a 12-cylinder RT-fl ex96C
engine with the rail unit under the platform on the left. Th e hydraulic
pipesfor the exhaust valve drives arch up from the exhaust valve actuators on
the servo oil rail, and the sets of triple high-pressure fuel injection pipes
rise up from the injection control units on the fuel rail.
Rail
unit
The
rail unit is located at the engine’s top platform level, just below cylinder
cover level. It extends over the length
of the engine. It is fully enclosed but has good maintenance access from above and from the
front. The rail unit contains the rail pipes
and associated equipment for the fuel,
servo oil and control oil systems. The starting air system is not included in
the rail unit. For engines with up to eight cylinders, the rail unities
assembled as a single unit. With greater numbers of cylinders, the engines have a mid gear drive
and the rail unit is in two sections
according to the position of the mid gear drive in the engine.
The
fuel common rail provides storage volume for the fuel oil, and has provision for damping
pressure waves. There is no need for
energy storage under gas pressure. The volume of the common-rail system and the
supply rate from the fuel supply pumps
are such that the rail pressure is very stable with negligible pressure drop
after each injection.
In
the RT-fl ex Size I, the high-pressure pipe for the fuel rail is modular with
sections for each cylinder and flanged to the individual injection control
units for each cylinder.
With
the Size IV, the high-pressure fuel rail was
changed to a single-piece rail pipe to shorten assembly time and to simplify manufacture. A single
length of rail pipe is installed in each section of the rail unit. The
only high-pressure pipe flanges on the
Size IV pipe are the end covers.
The
common rail system is designed with very high safety margins against material
fatigue. The fuel rail pipe for instance
has a very special inner shape to keep the stress amplitude in cross-bored
drillings remarkably low. The fact that,
by definition, common rails have almost
constant pressure levels further increases the
safety against high cycle fatigue cracking compared to conventional injection and actuator systems
with high pressure cycles.
The high-pressure rail is trace heated
from the ship’s heating system, using either steam or thermal oil. The simplification of the fuel rail for Size
IV, without intermediate flanges,
compared with that for Size I allowed the trace heating piping also to be
simplified. The trace heating piping and the insulation are both slimmer, allowing easier service access inside the
rail unit.
Fig.
12: Inside a Size IV rail unit during
assembly. The exhaust valve actuator (A) is mounted on the servo oil rail and the injection control
unit (B) is on the fuel rail. Next to the fuel rail is the smaller control oil rail (C) and the return pipe for
servo and control oil (D).
Injection
control unit (ICU)
Fuel is delivered from the common rail
to the injection valves through a
separate ICU for each engine cylinder. The ICU regulates precisely the timing
of fuel injection, accurately controls the volume of fuel injected, and sets
the shape of the injection pattern. The ICU has an injection control valve and
a Sulzer electro-hydraulic rail valve for each fuel injection valve. Th e rail
valves receive control signals for the
beginning and end of injection from the
respective electronic unit of the WECS (Wärtsilä Engine Control System).
There are three fuel injection valves in
each engine cylinder except for the RT-fl ex50 which has two. The fuel
injection valves are the same as those already employed in RTA engines, and are
hydraulically-operated in the usual way by the high-pressure fuel oil. Each
fuel injection valve in a cylinder cover
is independently controlled by the ICU for the respective cylinder so that,
although all the injection valves in an individual cylinder normally act in unison, they can also be programmed to
operate separately as necessary.
For Size I, the individual ICU are
arranged between the sections of rail
pipe but for Size IV the individual ICU are mounted directly on the rail pipe.
The ICU for Size IV was adapted from that in Size I with the same function principles for integral injection
volume flow but to suit the greater flow
volumes involved.
The common-rail system is purpose-built
for operation on just the same grades of heavy fuel oil as are already standard
for Sulzer RTA-series engines. For this reason, the RT-fl ex system
incorporates certain design features not seen in other common-rail engines
using middledistillate diesel oils. The key point is that, in the ICU, the
heated heavy fuel oil is isolated from the precision rail valves.
The Sulzer rail valves are bi-stable
solenoid valves with an extremely fast actuation time. To achieve the longest
possible lifetime, the rail valves are not energised for more than 4ms. This
time is sampled, monitored and limited by the WECS. The valves’ bi-stability
allows their position and status to be reliably controlled.
Exhaust
valve control
The exhaust valves are operated by a
hydraulic ‘push rod’, being opened by hydraulic oil pressure and closed by an
air spring, as in the Sulzer RTA engines with mechanical
camshafts.
But for RT-fl ex engines the actuating energy now comes from the servo oil
rail. There is one exhaust valve
actuator (also known as the partition device) for each cylinder.
In the exhaust valve actuator,
fine-filtered servo oil acts on the underside of a free-moving actuator piston,
with normal system oil above the actuator piston for valve actuation. The
adjacent hydraulic control slide is precisely activated by a Sulzer rail valve
and controls the flow of servo oil to the actuator piston so that the exhaust
valve opens and closes at precisely the correct time with appropriate damping.
The exhaust valve actuator employs the
same Sulzer rail valves as are used for the ICU.
The exhaust valve drive on top of the
valve spindle is equipped with two analogue position sensors to provide a
feedback on valve operation to the WECS.
The electronically-controlled actuating
unit for each cylinder gives full flexibility for exhaust valve opening and closing patterns. At the same time, the
actuating unit provides a clear separation of the clean servo oil and the
normal system oil. Thus the exhaust valve hydraulics can be serviced without disturbing
the clean servo oil circuit.
Operating
pressures and system energy
The normal operating pressure for the
fuel rail ranges up to 1000 bar. It is lowered for the best compromise between BSFC (brake specific fuel
consumption) and NOX emissions according to the respective engine load and to
keep the parasitic energy demand low. It was determined years ago in engine
tests in Winterthur that, under steady load conditions, the influence of fuel
injection pressure on specific fuel
consumption in low-speed engines diminishes with increasing injection
pressure. Thus, higher fuel injection pressures than are presently used in
large two- stroke low-speed engines have no real benefit. Should an increase
become necessary in the future, for instance in combination with other measures
to reduce NOX emissions, the RT-fl ex system is ideal to cope with it. The
additional, parasitic system energy would be very limited indeed, as the increase is about
proportional to the pressure increase.
Exhaust valve actuation requires a high
volume flow of oil. With an appropriately stepped hydraulic piston diameter on
the valve spindle both proper valve movement and low parasitic power could be
achieved at the same time. Additionally, the servo oil pressure of 200 bar
nominal is variably adapted to the minimum requirement over engine load to
ensure a proper function and minimal power demand.
Fig.
15: The exhaust valve drive on top of the exhaust valve spindle with the hydraulic cylinder and the air spring. The two
position sensors (not visible in this view) measure the radial distance to the
cone to determine the spindle’s vertical
Starting
air system
The
starting air system of RT-fl ex engines is very similar to that in Sulzer RTA
engines, except that its control is incorporated into the WECS. The starting
air system, however, is installed outside the rail unit to facilitate overhaul
access.
Electronic
control
All
functions in the Sulzer RT-fl ex system are controlled and monitored through
the Wärtsilä Engine Control System (WECS). This is a modular electronic system
with separate microprocessor control units for each cylinder, and overall
control and supervision by duplicated microprocessor control units. The latter
provide the usual interface for the electronic governor and the shipboard remote control and alarm systems. The
microprocessor control units, or
electronic control units, are mounted directly on the engine, either on the
front of the rail unit or adjacent to it..
An
essential input signal for WECS is the engine
crank angle. This is measured very accurately by two sensors driven from a stub shaft on the free
end of the crankshaft. The two sensors are driven by toothed belts so that
axial and radial movements of the crankshaft are not passed to the sensors. The
sensors are able to give the absolute crank angle position immediately that
electrical power is applied.
At
present RT-fl ex engines are being equipped with the WECS-9500 control system.
However, this will be superseded in 2005 by the WECS-9520 control system. The
new system provides simpler communication with the ship automation system and
easier wiring for the shipbuilder. Only one electronic module is used
throughout the new system, and there are fewer
equipment boxes which are also of simple, standard design. The
functionality of WECS-9520 is the same as that of the WECS-9500 system.
Fig.
16: Electronic control units beneath the
front of the rail unit of a Sulzer RT-fl ex96C engine.
Sulzer
RTA and RT-fl ex engines have standardized interfaces (DENIS) for remote
control and safety systems. The remote
control and safety systems are supplied to the ship by a variety of approved
manufacturers and DENIS (Diesel Engine Interface Specification) defines the interface
between the engine-mounted equipment and the shipboard remote control and
safety system.
With
RT-fl ex engines, the remote control sends engine manoeuvring commands to the
WECS. The remote control processes speed signals from the engine order
telegraph according to a defined engine load program and fuelling limitations,
and generates a fuel reference signal for the WECS according to DENIS.
The
safety system function in RT-fl ex engines is basically the same as in
conventional RTA engines, except that it has additional inputs for WECS
slowdown and WECS shutdown signals, and some outputs to the WECS system.
Reliability
and redundancy
Reliability
and safety has the utmost priority in the RT-fl ex system. Although particular
attention is given to the reliability of
individual items of equipment in the RT-fl ex system, the common-rail concept
allows for increased reliability and
safety through its inherent redundancy.
High-pressure
fuel and servo-oil delivery pipes, the electrically-driven control oil pumps,
and essential parts of the electronic systems are duplicated for redundancy.
Fig. 17: Inside one of the electronic control units
shown in figure 16.
The
duplicated high-pressure delivery pipes have stop cocks at both ends to isolate
any failed pipe. Each single pipe is adequate for the full delivery. All high
pressure pipes are double-walled for safety.
With
a more traditional injection arrangement of one
fuel high-pressure pump to each cylinder, a failure of one pump leads to the loss of that cylinder and
the imbalance in engine torque requires a drastic power cut. In contrast, with the RT-fl ex system in hich all high-pressure supply pumps are
grouped together and deliver in common to all
cylinders, the loss of any pumps has much less effect.
Indeed
with larger RT-fl ex engines having several fuel pumps and several servo oil
pumps there can be adequate redundancy for the engine to deliver full power
with at least one fuel pump and one servo oil pump out of action. Should
further pumps be out of action, there would be only a proportional reduction in
power.
Every
injection nozzle is independently monitored and controlled by the WECS. In case
of difficulties, such as a broken high pressure line or a malfunctioning
injector, the affected injection valve can be cut out individually without
losing the entire cylinder.
The
injection control unit ICU hydraulically excludes the injection of an
uncontrolled amount of fuel. During the entire working cycle of the metering
cylinder, there is never a direct hydraulic connection between fuel rail and
the injectors. The maximum injection quantity is limited to the content of the
metering cylinder as the travel of the metering piston is monitored. If the
travel of the metering piston should be
measured as out of range, the subsequent injections of that ICU will be
suppressed and an engine slow-down activated.
The
ICU also serves as a flow fuse: if the metering piston should travel to its
physical limit, it cannot return hydraulically and no further injection would
be possible until it is reset.
If
the stroke measuring sensor fails, the WECS system switches the ICU to a pure
time control and triggers the signal
based on the timing of the neighbouring cylinders. Two redundant crank angle
sensors measure the absolute crank angle
position which is evaluated through
WECS. WECS is able to decide which sensor to follow in case of a
discrepancy.
The
WECS main controller and all essential communication interfaces such as CAN-bus
cablings are duplicated for redundancy.
WECS monitors the momentary position of each rail valve for proper function of
each cycle before starting the next.
Fig.
18: Typical injection pattern of Sulzer RT-fl ex engines with all injection
nozzles acting in unison showing needle lift, fuel rail pressure, injection
pressure and cylinder pressure when all injection nozzles are operating
simultaneously. Note the sharp beginning and ending of injection, the lack of a significant pressure drop in the common
rail during injection, and the small rail pressure fluctuations.
Operation
and maintenance
Sulzer
RT-fl ex engines are designed to be user friendly, without requiring ships’
engineers to have any special additional skills. Indeed the knowledge for
operating and maintenance of RT-fl ex engines can be given in the same form as
Wärtsilä’s usual one-week courses for Sulzer RTA-series engines given to ships’
engineers and owners’ and operators’ shore staff . The training time usually
given to the camshaft system, fuel pumps, valve actuating pumps and reversing
servomotors is simply given instead to the RT-fl ex common-rail system.
It
has been seen from shipboard operation of the
RT-fl ex engines that the ships’ engineers quickly become comfortable
operating the engines.
Key
features of the Sulzer RT-fl ex system
The
key features of the Sulzer common-rail system can be summarised as:
• Precise volumetric control of fuel
injection, with integrated flow-out security
• Variable injection rate shaping and
variable injection pressure
• Possibility for independent action and
shutting off of individual fuel injection valves
• Ideally suited for heavy fuel oil
• Well-proven standard fuel injection
valves
• Proven, high-effi ciency common-rail
pumps
• Lower levels of vibration and internal
forces and moments
• Steady operation at very low running
speeds with precise speed regulation
• Smokeless operation at all speeds.
Benefi
ts from the Sulzer RT-fl ex system
At
its heart, the Sulzer RT-fl ex engine is the same reliable, basic engine as the
existing Sulzer RTA engine series. The power ranges, speeds, layout fields and
full-power fuel
consumptions
are the same for both engine versions.
For
shipowners, the principal benefits of Sulzer RT-fl ex engines with their
electronically-controlled common rail systems are:
•
Reduced part-load fuel consumption
•
Smokeless operation at all running speeds
•
Very low, stable running speeds at about ten per cent nominal speed
•
Easy engine setting for less maintenance
•
Longer times between overhauls (TBO) expected, primarily through better load balance
between cylinders and cleaner combustion at all loads.
Comments
below are made on just the first three of the above points as these are the
ones which have so far been definitely quantified.
Low
exhaust emissions
A
clearly visible benefit of Sulzer RT-fl ex engines is their smokeless operation
at all ship speeds. It helps give a ‘green’ image.
This
was well demonstrated in the testing of the first RT-fl ex engine and during
the sea trials of the Gypsum Centennial.
The
superior combustion performance with the common-rail system is achieved by
maintaining the fuel injection pressure at the optimum level right across the
engine speed range. In addition, selective shut-off of single injectors and an
optimised exhaust valve timing help to keep smoke emissions below the visible
limit at very low speeds.
The
precision and flexibility in engine setting given by the RT-fl ex system
facilitates compliance with the NOX regulation of Annex VI of the MARPOL 73/78
convention, usually referred to IMO NOX regulation.
The
flexibility of the RT-fl ex engines will also allow a lowering of NOX emissions
if the corresponding increase in BSFC is acceptable. With common-rail
injection, a wide variety of injection patterns can be generated. The injected
quantity of fuel can be divided, for pre-injection, triple injection, etc. The
Sulzer RT-fl ex engine, with its individual fuel valve control, also has the
unique ability to vary individually the injection timing and sequence between
the three fuel injectors in each cylinder and thus to generate a tailor-made
heat release.
In
engine tests, this degree of flexibility has proved useful to reach NOX
emissions of 20 per cent below the IMO NOX limit with a moderate BSFC increase
of 2.3 per cent.
Very
slow running
Sulzer
RT-fl ex engines have also demonstrated their ability to run stably at very low
speeds, lower than engines with mechanically-controlled injection. They can run
without smoking at about ten per cent nominal speed. This makes for easy ship
handling when manoeuvring or in river and canal passages.
Fig.
19: Sulzer RT-fl ex engines have the unique ability to shut off individual fuel
injectors, here shown schematically. This feature is used to assure clean
combustion for smokeless, stable running at very low speeds.
Such
slow running was well confirmed in service in the Gypsum Centennial.
Slow running was taken to a new ‘low’ during the testing in May/June 2004 of
the first 12-cylinder RT-fl ex96C engine. Owing to its number of cylinders, it
could run steadily at just seven revolutions per minute.
The
very slow running is made possible by the precise control of injection,
together with the higher injection pressures achieved at low speed, and
shutting off injectors at low speeds. Reducing the number of injection valves
in operation makes injection of the reduced fuel quantities more efficient,
especially as the injection pressure is kept up to a higher value than in a
mechanically-injected engine at the same speeds.
Shutting
off injectors provides more stable operation with better distribution of engine
load and thermal loads than if very slow
running was to be achieved by cutting out whole cylinders.
Shutting
off injectors is enabled by the separate control of individual fuel injection
valves. This feature is unique to Sulzer RT-fl ex engines. Usually the
injection valves operate in unison but, as the engine speed is reduced, one
injection valve can be shut off and at a lower speed a second injection valve
can be shut off . Thus at minimum
speed,
the engine runs on all cylinders but with just one injection valve in each
cylinder.
If
the RT-fl ex engine then runs for a period in singleinjector operation, the
electronic control system switches between the three injection valves in a
cylinder so that the thermal load is equalised around the combustion chamber.
Fuel
consumption flexibility
Sulzer
RTA engines have always been highly competitive in fuel consumption right
across the load range owing to the use of variable injection timing (VIT).
Variable exhaust valve closing (VEC) was also added in RTA84Tengines in 1991 to
reduce further the part-load BSFC. These benefits have already been carried
over to the electronically-controlled common-rail systems of the RT-fl ex
engines.
At
the first stage of development of RT-fl ex engines, however, the main objective
has been to achieve the same performance standards as are achieved in the
mechanical-camshaft engines, particularly with respect to power, speed, fuel
consumption, exhaust emissions, cylinder pressures, etc. Thus the curves of
brake specific fuel consumption (BSFC) of the first RT-flex engines have been
the same as with corresponding RTA engines,or perhaps slightly lower in the
part-load region. As the fuel injection pressure at part-load is kept higher
with the common-rail injection system, combustion is sufficiently better to
have a beneficial effect on fuel consumption in part-load operation.
Recently
an alternative fuel consumption curve was introduced with Delta Tuning to
provide even lower BSFC at loads less than 90 per cent full load. For both the
original (Standard) and Delta Tuning curves, the RT-fl ex engines comply with
the IMO NOX regulation. the shape of the new BSFC curve given by Delta Tuning.
The BSFC is lowered in the mid- and low-load range, thereby increasing the NOX
emission levels at those load points, but then has to
be
increased at high engine loads (90–100 per cent load) for a compensating
reduction in NOX levels.
Delta
Tuning was first applied in the first Sulzer 8RT-fl ex96C engine which
completed its official shop test on 9 April 2004.
Fig.
20: Sulzer 7RT-fl ex60C engine in Wärtsilä’s Trieste factory in October 2002.
It develops 16,520 kW at 114 rpm, and
measures about 11.4 m long by 10.5 m high. Above the top platform, the
rail unit covers can be seen open.
Common
rail is now an industrial standard for diesel engines. It has been proven to be
an tremendous step forward for all sizes
of diesel engines from automotive engines up to the largest low-speed
two-stroke engines. In this environment, Sulzer RT-fl ex engines have become
well accepted by shipowners. Shipowners’
confidence is being encouraged by the good operating experience with the
growing number of RT-fl ex engines in service.
The
combination of common-rail concepts and fully-integrated electronic control
applied in Sulzer RT-fl ex engines clearly has excellent potential for future
development. It gives the large degree of flexibility in engine setting and
operation, together with reliability and safety, which are required to meet the
challenges in future marine engine applications in terms of emissions control,
optimized fuel consumption, insensitivity to fuel quality, ease of use,
operational flexibility, etc.
Fig. 21: The world’s most powerful common-rail engine,
the Sulzer 12RT-fl ex96C engine develops 68,640 kW at 102 rpm, and measures
about 24 m long by 13.5 m high. It passed its official shop test in June 2004.
The supply unit shown in figure 4 can be seen at the middle of the engine.
chapter-6
The major steps in two-stroke diesel technology have been
surprisingly few over the past century: airless fuel injection in the 1930s,
welded construction in the late 1940s, and
exhaust gas turbocharging and the use of heavy fuel oil both in the
1950s. Now we have another major step –
electronically controlled common-rail
fuel injection introduced in the Sulzer RT-flex engines.
Although common-rail fuel injection is itself not new, the
addition of integral electronic control allows full use to be made of the
flexibility possible with common-rail injection. Wärtsilä has therefore
expanded the Sulzer RT-flex engine range to include cylinder bore sizes from
500 to 960 mm.
These are the most advanced low-speed marine engines available in
the world today. The Sulzer RT-flex electronically controlled common-rail
system has already been well described in recent issues of Marine News.
However, we should note some key dates:
·
1981: First tests with electronically controlled fuel injection on
a Sulzer low-speed engine, using individual, hydraulically operated fuel
injection pumps.
·
1990 March: World’s first multicylinder electronically controlled
uniflow two-stroke engine is started on the Winterthur test bed. Tested until
1995.
·
1993: Project started to develop the Sulzer RT-flex common-rail
system.
·
1996: Component testing began for the Sulzer RT-flex common-rail
system.
·
1998 June: Starting of the first Sulzer RT-flex full-scale engine
on the Winterthur test bed.
·
2000 February: Order for the first series-built Sulzer RT-flex
engine.
·
2001 January: Official shop test of the first series-built Sulzer
RT-flex engine, the Sulzer 6RT-flex58T-B in Korea.
·
2001 September: Sea trials of the ‘Gypsum Centennial’ with the
Sulzer
·
6RT-flex58T-B engine.
·
2002 October: Official shop test of the
first Sulzer RT-flex60C engine.The latest step in the above
chronology is particularly significant because the Sulzer RT-flex60C engine is the first large
low-speed marine diesel engine designed
from the bedplate up solely as an electronically controlled engine
with common-rail fuel injection. In fact, it is not available in any other
form.
The Sulzer RT-flex60C
The market need for a new Sulzer two-stroke engine design in the
region of 600 mm bore was seen a few years ago when an increasing number of
container liners of 5500 TEU capacity or larger were being ordered. It was
evident that there would be a growing market for container feeder vessels to
serve these larger container liners, and also that the sizes of the feeder
vessels themselves would tend to become
larger, perhaps in the capacity range of 1200-3000 TEU. Market research
among shipowners and shipbuilders showed
that the various sizes of feeder vessels would need compact engines in the power range of around 12,000
to 19,000 kW for the envisaged range of
ship speeds. There was clearly a need for more power than is available from the
Sulzer RTA62U-B type, and with a higher shaft speed than the Sulzer RTA58T-B
engine type.
Thus the decision was made to introduce the Sulzer RT-flex60C which
would cover the required power range with
five
to eight cylinders at an output of 2360
kW/cylinder. The nine-cylinder model was added later to extend the power range to 21,240 kW. The rotational speed
selected, 114 rpm, is a little faster than
would be ideal hydrodynamically for
suitable propellers but it was selected as the best fit between the
priorities of operating and manufacturing costs.
The
first pair of Sulzer RT-flex60C engines were specified by Agricultural Export
Co (Agrexco) and Münchmeyer, Petersen GmbH & Co KG for the propulsion of
two 13,200 dwt containerized reefers contracted in Portugal towards the end of 2000. Each seven-cylinder
Sulzer RT-flex60C engine has a maximum
continuous power of 16,520 kW at 114 rpm.
The
engines were built at Wärtsilä’s Trieste
factory. The first engine completed its official shop test on 14-15 October
2002.
The
second engine successfully passed a type approval test on 17-20 December 2002.
This test was witnessed by the
representatives of the classification societies, as well as the
shipowners and shipbuilder.
Four
similar Sulzer 7RT-flex60C engines are also being built under licence at
Hyundai Heavy Industries Ltd in Korea for four 30,000 dwt multipurpose
carrierscontracted at Shanghai Shipyard in China by Chinese-Polish Joint Stock
Shipping Co (Chipolbrok).
The
first two of these engines successfully
passed their official shop tests on 22-28 January and 6-7 March 2003.
Testing
Sulzer RT-flex60C engines
The
four Sulzer RT-flex60C engines so far tested have been put through the usual
test programmes for new engine types.
For
all four engines, initial tests runs were employed to optimize the
turbocharging and fuel injection equipment. The usual test measurements were
taken as for all production engines to con firm their predicted performance in
terms of power, speed, fuel consumption, etc.
However,
the first two engines were subjected to further tests withmeasurements of
component stresses and temperatures to confirm design calculations.
This
can be illustrated by the combustion space which, for the Sulzer RT-flex60C,
follows well-established Sulzer RTA practice. All the surrounding components
are bore-cooled. The piston crown employs the usual jet-shaker oil cooling
principle with an arrangement of cooling bores in the crown so that the surface
temperatures of the crown are moderate with a very even distribution.
An
important part of the test programmes was final adjustment and thorough testing
of the RT-flex systems, particularly of their electronic control system.
During
the tests, the four engines all
performed as expected. The electronic systems were noticeably stable.
The engines could be started, stopped, manoeuvred, taken up to load and
unloaded without any hindrance.
Type
approval for RT-flex system
The
Sulzer 6RT-flex58T-B engine of the Gypsum Centennial entered service with
individual approval for the RT-flex system from the classification society
Lloyd’s Register of Shipping. However, following the successful type approval
test of the second Trieste-built Sulzer RT-flex60C engine in October 2002, the
RT-flex system has received full classification society approval for general
application in ships.
RT-FLEX
service experience
In parallel with the building and
testing of the Sulzer RT-flex60C,
service experience has been accumulating with the first RT-flex engine. This is a Sulzer 6RT-flex58T-B
engine which passed its official shop test in January 2001 and is installed in
the 47,950 dwt bulk carrier Gypsum Centennial. The ship was built for her
owners Gypsum Transportation Ltd (GTL) of Bermuda by Hyundai MipoDockyard in
Ulsan, Korea. The Sulzer RT-flex main
engine has a maximum continuous output of 11,275 kW at 93 rpm.
The ship was delivered in September 2001
and the service experience with the engine has since been very good, with
currently more than 8000 hours’ operation.
This Sulzer 6RT-flex58T-B is the world’s
first series-built large low-speed engine with electronically controlled
common-rail fuel injection. It must be remembered that this engine was built to
operate using only the electronically controlled common-rail system with no
alternative. It went to sea as a fully
industrialized product capable of continuous heavy-duty commercial
operation. After some ‘teething problems’ were satisfactorily solved, the
engine achieved this performance with very good success.
In October 2002, the engine was inspected in Tampa, Florida, as part of
the ship’s guarantee ocking after her
first year’s service, 5295 running hours. The engine was found to be in good condition.
The few shortcomings could all be corrected. The RT-flex system was thoroughly
inspected to assess the condition of all hardware. Certain components were exchanged for later detailed inspection.
The opportunity was also taken to
exchange components for new, improved designs where appropriate. For example, the control oil
pumps which had failed in service were replaced by a new design, and given elastic mountings and flexible hoses.
The
roller guide of a fuel pump was found to be seized. The problem was
insufficient clearance between the roller guide and its casing. These
components were thus renewed. This and previous exchanges meant that all fuel
pumps were then of fully modified
design. Since the guarantee docking, the RT-flex engine has run well, behaving
much as it had done during the months immediately before the docking
inspection.
RT-flex
programme extension
The excellent experience with the
Sulzer RT-flex system, in the research
engine since June 1998, in the shop testing of now two Sulzer 6RT-flex58T-B and
four Sulzer 7RT-flex60C engines, and in the shipboard service of the first 6RT-flex58T-B since
September 2001, has encouraged Wärtsilä to extend the Sulzer RT-flex engine
programme to both lower and higher powers. The objective is to offer a
comprehensive programme of low-speed engines with electronically controlled
common-rail systems.
Sulzer
RT-flex50
Following the RT-flex58T-B and
RT-flex60C engines, the first addition to the programme is the new Sulzer
RT-flex50 engine which is currently
being developed. The Sulzer RT-flex50 is being adapted by Wärtsilä from the
conventional Sulzer RTA50 engine with camshaft-based fuel injection, etc.,
which is being jointly developed by Wärtsilä and Mitsubishi Heavy Industries
Ltd.
Of 500 mm bore by 2050 mm stroke, the
RT-flex50 has a maximum continuous power of 1620 kW/cylinder at 124 rpm. With
five to eight cylinders, it will cover a power range of 5650-12,960 kW at 99 to
124 rpm. It thus offers the right powers and speeds for a wide variety of ship
types including the new generation of Handymax and Panamax bulk carriers, large
product tankers, container feeder vessels and medium-sized reefer ships.
The
first Sulzer RT-flex50 engine is
scheduled to begin testing in the fourth quarter of 2004.
Sulzer
RT-flex96C and RT-flex84T-D
The RT-flex concept will also be
extended to the highest powers with the Sulzer RT-flex96C and RT-flex84T-D engines. The Sulzer RTA96C
engine type has been popular for the propulsion of container liners. A total of
139 RTA96C engines are now in service or on order.
They currently extend from 7-cylinder
engines of 40,040 kW in 3000 TEU ships to the 68,640 kW 12-cylinder engines for
the largest ships of more than 8000 TEU.
The
Sulzer RTA84T engine type is employed
solely for the propulsion of VLCCs and ULCCs, predominantly in the 7-cylinder
model. The current Sulzer 7RTA84T-D gives 28,700 kW.
The benefits of the RT-flex engines –
smokeless operation, better fuel economy, reduced maintenance and lower
steady running speeds – will certainly
be attractive for both types of ship.
The first Sulzer RT-flex96C engine
is scheduled for shop testing in April
2004, with delivery in the ship towards the end of 2004. The first RT-flex84T-D
can be built in mid-2005, according to market requirements.
Chapter-7
Environmental Friendly Two-stroke Marine
Diesel Engine,
“MITSUBISHI UEC Eco-Engine”
The environmental friendly diesel engine, “UEC Eco- Engine” is
named for the letters of “Eco” which are found in its design goals of Ecology,
Excellent engine Condition, Easy Control, and Economy, all by Electronic Control,.
The UEC
Eco-Engine is an engine that has been developed by modifying a conventional
engine, of which fuel injection system, exhaust valve driving system, engine
starting system, and cylinder lubricating system are controlled electronically.
As a result, the engine structure is much simplified by eliminating the
conventional large mechanical parts, such as cams, camshaft, and driving gears.
The modification and conversion to an electronic control system makes it
possible to adjust optimal timing of the fuel injection and exhaust valve
actuating and fuel injection rate according to the engine operating condition,
ambient conditions, and fuel properties. As a result, engine performance can be
optimized across the entire load range.
Therefore, the consumption of fuel oil and cylinder lubricating oil are both reduced as
a result, the emission characteristic with regards to NOX and smoke can be
improved. Higher reliability of the combustion chamber can be ensured by the
optimization of the operation condition, and the higher economical operation
can be achieved. Furthermore, since the starting performance is improved and an
extremely lower revolution operating can be achieved by the realization of
better maneuvering capability.
Fig. 1 Fundamental structure of engine
The UEC
Eco-Engine will be a leading engine in the next generation, which has the
above-mentioned various advantages in addition to the highly economy and highly
reliability that has been proven on the conventional UEC engines.
3.
Overview of electronic control system
3.1 Fuel
injection system
Fig. 2
shows the configuration of the fuel injection system. The fuel injection system
consists of pilot solenoid valve, main valves, fuel injection pump, and fuel
injection valves. The pilot solenoid valve consists of a main solenoid valve
and sub solenoid valve. The fuel injection rate can be controlled by actuating
the main and sub solenoid valves at different times. As a result, the initial
combustion temperature is reduced making it possible to reduce NOX emission,
compared with the conventional engines.
Usually there is trade-off relationship between fuel oil
consumption and NOX emission . The UEC Eco-Engine is able to reduce NOX
emissions by about 10 to 15% compared with conventional engines, at same fuel
oil consumption levels, when priority is given to the NOX mode. On the other
hand, fuel oil consumption can be reduced by 1 to 2%, at the same NOX emission
levels, when priority is given to fuel oil consumption. In addition, in the UEC
Eco-Engine, the operation mode can easily be switched at the control panel, so
that it becomes possible to choose the optimal operation at any condition.
In the conventional engines, fuel injection pressure gets lower
at low load operation since it depends on the rotational speed of the engine.
On the other hand, in the UEC Eco-Engine, since the fuel injection is performed
using high-pressure hydraulic oil throughout the entire load range, fuel
injection pressure is maintained at nearly maximum levels, even under low
loads. Therefore, appropriate injection pressure improves combustion condition
at lower load and reduces smoke emission significantly
Fig. 2 Configuration of fuel injection
system Fig. 4 Relation between
fuel oil consumption and NOx emission
3.2
Exhaust valve driving system
The
configuration of the exhaust valve driving system is shown in Fig. 6 .
The
exhaust valve driving system consists of a pilot solenoid valve, main valves,
lower actuating unit, upper actuating unit, and exhaust valve. The timing of
the opening of the exhaust valve can be optimized by adopting an electronic
control system throughout the entire load range. Accordingly, the timing for
opening the exhaust valve can be delayed by increasing the velocity of the
opening, so that the effective work of the piston can be increased.
These
optimizations result in an improvement in fuel oil consumption of approximately
1 to 2%, compared with the conventional engines.
Electronic control
Fuel
injection, exhaust valve actuating, and starting air systems are controlled electronically and are
optimized for all operation loads.
Ecology
NOx
emission can be reduced and smokeless operation achieved. In addition, water
injection system, a drastic NOx reduction technology, may be applied in
combination with the Eco-system to cope with the stricter NOx emission
regulations anticipated in the future.
Economy
Lower
specific fuel oil consumption especially in partial loads can be obtained, and
this can lead to less running cost.
Easy
control
Eco-Engine
assures stable low load operation with good engine performance. Easy change of
operating modes and fine tuning of operating conditions are also possible
during operation.
2.5 Excellent engine
condition (higher reliability)
Appropriate
fuel injection pressure and optimum injection timing, which are the most
favorable for combustion conditions at each load, can further enhance the
reliability of the hot components proven
in UEC conventional engine.
- HISTORY OF UEC ECO-ENGINE PROJECT
Anticipating
possible future requirements, we began to study various solutions as early as
1988. Over a long period, the
fundamental system has been verified on single cylinder research engines, the
NC45 (45 cm bore) and the NC33 (33 cm bore) at the MHI Nagasaki Research & Development Center. The first
generation of the electronic system was tested on the NC45 research engine from
1988 to 1993, and more than 1,200 hours of various operations verified the system’s
performance and reliability. The test results satisfied the concepts of the
system. The second generation of the electronic system followed on the NC33
research engine and was tested until 1997. Its results boosted our belief that
an electronically controlled engine has advantages to comply with future
industry requirements. Figure 1 shows the NC33 research engine.
Based
on the above-mentioned good experimental results, UEC Eco-Engine project
started in early 2000 to meet the growing market demand. The 7UEC33LS Ⅱ engine, a stationary
diesel engine generating set at the MHI Kobe Shipyard & Machinery Works,
was converted to the first full-scale Eco-Engine in December 2001 and has
proved its reliability through three years of various operations. In this engine,
the electronic control system was retrofitted to a conventional engine. The
aspects of the engine can be seen in Figure 2. The main particulars of the
engine are listed in Table 1.
Retrofitted electronic-control device view
from driving end
Fig. 1 NC33 research engine at MHI
Nagasaki Research & Development
Center
|
view
from fore end
Fig.
2 7UEC33LSII-Eco at MHI Kobe
Shipyard
and Machinery Works
As mentioned above, we
concentrated on the reliability and performance of the electonically controlled
engine through a long span of verification tests and successfully confirmed
high reliability as well as high performance. We will introduce the first commercial
project of UEC Eco-Engine in a later section.
4. MHI’S LOW EMISSION
TECHNOLOGY
Fig.
3 Applications to low NOx emission technology
In
general, our technological plans to cope with further strict NOx regulations
are described in Figure 3. To comply with the International Maritime
Organization’s (IMO) first regulation, which took effect in May 2005, we have
already delivered all our engines in compliance with the regulation by
optimization of the fuel injection nozzle and fine tuning of our traditional
engines.
To
satisfy the second regulation, which is estimated to be 20 to 30% stricter than
the first regulation, we plan to apply UEC Eco-Engine or a water injection
system in combination with a conventional engine. To satisfy the third
regulation, we will combine UEC Eco- Engine with a water injection system.
According to the severity of the regulations, other technologies might be
needed, for example, the Selective Catalytic Reactor (SCR).
Anticipating
future demand, we will maintain our efforts to develop the necessary
technologies.
5. FUNDAMENTAL
STRUCTURE
The
engine’s fundamental structure is seen in Figure 4, where it is compared with a
conventional engine.
Fig.
4 Fundamental structure of engine
By
electronic control, engine structure is greatly simplified by eliminating such
conventional large mechanical parts as the fuel and exhaust cams, the camshaft,
and the driving gears. An electronic control system with a hydraulic oil supply
system is added. Accordingly, maintenance on these mechanical components is
also eliminated, and the computational tuning of engine operating conditions
also eliminates the delicate adjustment
work on these parts both in the shop and on board.
Simple
fine tuning of operating conditions are possible during operation, this means
that engine operation will be much more flexible than conventional engine.
An
overview of the fuel injection and exhaust valve actuating mechanisms are
described in Figure 5. The fuel injection pump and the lower exhaust valve driving gear are actuated by 320 bar
hydraulic oil. This pressurized oil is accumulated in the accumulator
block mounted at each cylinder. The connection
blocks are applied
Fig.
5 System overview of cylinder component
The hydraulic power for
fuel injection and exhaust valve actuation is controlled by an on/off type
solenoid valve unit and an engine control system. The timings of fuel injection
and exhaust valve open/close are also controlled electronically to achieve the best
condition for any operation mode. This concept simplifies readjustments needed
to maintain better operating conditions.
Downstream
from the fuel injection pump and the lower exhaust valve driving gear, the same
design concepts of the conventional system are applied to reduce crew education
for new maintenance work about such components
6. FUEL INJECTION
SYSTEM
Figure
6 shows a cross section of the fuel injection system for UEC Eco-Engine. The
fuel injection pump has a similar structure to the conventional mechanical
models but is rather simplified. This means that the crew is already familiar
with maintenance for the fuel injection pump, reducing overhaul time.
Fig.
6 Fuel injection system
As
one of its main features, two sets of on/off type solenoid valves are mounted to control the injection
pattern, which depends on the operating load, and to improve the trade-off
relationship between thermal efficiency and NOx emission.
The mechanism to change
the fuel injection pattern is shown in Figure 7. This is our patented
technology put into practice by a pair of on/off type solenoid valves.
Fig.
7 Controlled fuel injection pattern
In
addition, we are now incorporating a water injection system with Eco-Engine to
comply with future anticipated stricter
NOx emission regulations.
A feedback control
function is applied to control the fuel injection volume to compensate for the
equivalent thermal load and individual cylinder control. Fuel pump stroke is
monitored by twin gap sensors at each cycle. This emphasizes the system’s
reliability through observation of the control system.
7. EXHAUST VALVE
ACTUATING SYSTEM
Figure 8 shows a cross
section of the exhaust valve actuating system for UEC Eco-Engine.
The
exhaust valve open and close timings are also controlled by electronic control
system using the on/off solenoid valve unit. Accordingly, timings are optimized
depending on the operating load. For precise timing control, a feedback control
function is applied by observation of the exhaust valve lift.
The
actuating mechanism is similar to conventional mechanical ones and inherits
their reliability and method of maintenance.
Fig. 8 Exhaust valve actuating system
8. CONTROL VALVE UNIT
Solenoid valve units
are key components of an electronically controlled engine. The valve units of a
large electronically controlled engine require very quick response, high flow
rate, and long life cycle. We started valve development in 1999 and have
already confirmed its performance.
The most important
issue is reliability for a long life cycle. Thus, endurance tests were undertaken. The endurance test of valve
unit finished 300 million cycle that corresponds to approximately six years of
actual operation on board, and it satisfied its requirements.
The small size unit for a bore 40 cm class engine has also been
verified in the 7UEC33LS Ⅱ -Eco
prototype. The performance and endurance of the medium size unit for a bore 60
cm class engine were verified by a test bench similar to the fuel injection
system in Figure 9.
Fig.
9 Control valve unit on test bench
9.
STARTING AIR SYSTEM
Figure
10 compares the starting air systems. The conventional starting air control
valve is eliminated, and solenoid valves and a control air pipe are added. The
starting valves are electronically
controlled to achieve better performance and flexibility for engine start and
crash astern.
Fig. 10 Comparison of
starting air systems
10. HYDRAULIC OIL
SUPPLY SYSTEM
A hydraulic oil supply
system (see Figure 11) is another key component of Eco-Engine.
11. ECO-ENGINE CONTROL
SYSTEM
An
engine control system is prepared for the Eco Main Controller (EMC) and
installed in the control room to interface with the Remote Control System. The
Local Control Box (LCB) and the Eco Cylinder Controller (ECC) are mounted on
the engine. These controllers are connected by a duplicated network line. An overview of the
control system is provided in Figure 12.
Fig. 12 Control system overview
11.1 EMC
For
duplication purposes, the controller is comprised of two units operating
parallel and performing the same task; they
are duplicates of each other. If the active EMC fails, the other unit will
assume control without any interruption.
EMC performs the
following tasks:
- Speed governor functions
- Start/stop sequences
- Timing control of fuel injection, exhaust valve actuation,
and
starting air systems
·
Control
of the hydraulic oil supply system
·
Alternative
operation and control modes
·
Network
functions
·
Malfunction
observation of entire control system
11.2 ECC
Each
ECC, which is mounted on individual cylinder,
performs the orders for the timing of fuel injection, exhaust valve
actuating, and starting air systems.
11.3 LCB
This
controller provides engine side control for emergency if the Remote Control System or both EMCs
fail. This means that the operator can choose two operations, which are
controlled by EMC or LCB.
We
developed an evaluation tool called the Real Time Simulator (RTS), as shown in
Figure 13, that verifies control sequences by simulating such engine running
conditions as start/stop, crash astern, rough seas, and malfunctions. The image
of this tool creates a virtual engine in the simulator.
We
verified the first commercial control system by using this tool before running
it in our shop. In addition, the reliability of the control system’s hardware
was evaluated against surrounding conditions, including vibration, temperature,
and noise.
12. THE FIRST
COMMERCIAL ECO-ENGINE
In
June 2004, the manufacture of the first commercial UEC Eco-Engine, 8UEC60LSⅡ-Eco,
was completed. Its main particulars are listed in Table 2. Figures 14 and 15
show pictures of the engine in our shop. Its comprehensive tests were carried
out in our shop for three months in 2004, and a sea trial was held in May 2005.
This section introduces their major results.
Table 2 Main
particulars of 8UEC60LSⅡ-Eco
12.1 Economy and Low emission mode
We
evaluated actual operating conditions by applying fuel injection controls. To
operate Low Emission Mode, NOx emission reduction can be obtained at the same
SFOC. On the other hand, to select Economy Operating Mode, SFOC can be reduced
1 to 2% compared with conventional engines. The
engine operation mode can be easily changed over by a switch on the
controller.
From the results of 8UEC60LSⅡ-Eco
shop tests, we found that trade-off between thermal efficiency and NOx emission
can be improved as we planned. Figure 16 compares SFOC and NOx emission between
fuel injection controls ON and OFF in normal load. With fuel injection control,
we achieved Δ 10.2%
NOx emission in equivalent SFOC.
Fig. 16 Improvement by fuel injection
control
12.2 Engine Performance
Figure
17 shows the performance curve of 8UEC60LSⅡ- Eco with the test
results of economy and low emission modes. As expected, especially in lower
loads, economy mode decreases SFOC, and low emission mode decreases NOx
emission.
Fig. 17 Performance curve of 8UEC60LSⅡ-Eco
12.3 Smoke
The
fuel injection system is significantly improved with electronic control system.
Thus, smokeless operation can be achieved for whole operation load. Figure 18
compares the Bosch Smoke Number measured on 8UEC60LSII-Eco.
Fig. 18 Smoke measurement results of
8UEC60LSⅡ-Eco
12.4 Cylinder lub. oil
consumption
Eco-Engine
has electronically controlled cylinder lubricating system to obtain precise
injection quantity and optimum injection timing at each load, which lead to
higher reliability on piston rings and cylinder liner and lower operation
costs. Figure 19 shows the transition of lubrication oil feed rate of 8UEC60LSⅡ-Eco
in shop tests. At the end of shop tests, feed rate decreased less than 1.0
g/PSh.
Fig.
19 Lub. oil feed rate on shop test
12.5 Inspection results
Inspection results after sea trials
revealed that each part was maintained in excellent condition. Figures 20 and
21 show inspection results.
Fig.
20 Inspection results after sea trial (1)
(d)
Cylinder Liner
Fig.
21 Inspection results after sea trial (2)
13.
SUMMARY OF ADVANTAGES
As
a summary, the distinctive advantages of UEC Eco-Engine are as follows:
13.1 Environmental
friendliness
Smokeless
operation can be achieved by appropriate fuel injection pressure at any load.
Reduction of NOx emission can be obtained by tuning the fuel injection timing
and pattern at any load.
13.2 Lower Specific Fuel
Oil Consumption (SFOC)
The
timing of fuel injection and exhaust valve actuation can be flexibly optimized
by electronic control according to engine operating loads, atmospheric
conditions, and fuel oil properties. Accordingly, lower SFOC can be obtained,
especially in partial loads.
13.3 Easy control
(better maneuverability)
Eco-Engine
assures stable continuous low load operation, even for extremely low loads,
with good engine performance ecause of improved combustion conditions thanks to
appropriate fuel injection pressure and optimized fuel injection timing and
exhaust valve actuating in lower loads.
13.4 Higher reliability
In
Eco-Engine, appropriate fuel injection pressure, which is the most favorable
for combustion conditions at any load, will urther enhance the high reliability
of the hot components proven on conventional UEC engines, such as piston
crown,piston ring, cylinder liner, and exhaust valve.
13.5 Flexible operation
Easy
changes of operating modes and fine tuning of operating conditions are possible
during operation.
13.6 Less maintenance
With
electronic control system, the engine structure is significantly simplified by
eliminating conventional large mechanical parts. Accordingly, maintenance on
these mechanical components is eliminated, and the computational tuning of
engine operating conditions obviates the need for delicate adjustment work on
these parts both in the shop and onboard.
Chapter-8
WARTSILA DUEL FUEL ENGINES
Dual-fuel
engines:
Ø Gas
engine technologiesGas-diesel, spark-ignition gas and dual-fuel engines
Ø Dual-fuel
engine applicationsOn land, at sea and in LNG carriers
Ø Dual-fuel
engine parametersWärtsilä 32DF, 34DF and Wärtsilä 50DF
Ø Dual-fuel
engine systemsGas fuel, pilot fuel
Ø Future LNG fueled vessels
Gas engine technologies
Gas-diesel (GD) engines:
Ø Runs
on various gas / diesel mixtures or alternatively on diesel.
Ø Combustion
of gas, diesel and air mixture in Diesel cycle.
Ø High-pressure
gas injection.Spark-ignition gas (SG) engines:
Ø Runs
only on gas.
Ø Combustion
of gas and air mixture in Otto cycle, triggered by spark plug ignition.
Ø Low-pressure
gas admission.
Dual-fuel (DF) engines:
Ø Runs
on gas with 1% diesel (gas mode) or alternatively on diesel (diesel mode).
Ø Combustion
of gas and air mixture in Otto cycle, triggered by pilot diesel injection (gas
mode), or alternatively combustion of diesel and air mixture in Diesel cycle
(diesel mode).
Ø Low-pressure
gas admission.
v
Engine performance
v
Higher output
v Gas system
v Double wall gas piping
v
Lubricating oil system
v
Components built on engine
v
Compressed air system
v
Direct air injection into cylinders
v Charge air and exhaust gas system
v SPEX system
v Automation system
v UNIC engine control system
IMO NOx–Regulation 13
•New
buildings (diesel engines > 130 kW): Tier II from 2011; Tier III to be
applied in designated areas from 2016* (Tier II to be applied outside these
areas)
•Existing
ships: Tier I to be applied for vessels constructed between 1990 and 2000
(diesel engines > 5000 kW and > 90 liters / cylinder). Some exemptions
are considered
IMO SOxand PM
–Regulation 14
v Low Natural Gas Emissions 25-30%
lower CO2
v Low Carbon to Hydrogen ratio of fuel 85% lower NOX
v Lean burn concept (high air-fuel ratio) No SOXemissions
v Sulphur is removed from fuel when liquefied 50% lower PM Particulates
v Particulates vary across operating range No visible smoke No
sludge deposits extends engine life
Emission comparison
Dual-Fuel
engine application: conclusions
Ø LNG
utilized as marine fuel is cost competitive
Ø Technology
is already available and well proven in the marine market
Ø Dual-Fuel
Engines represent the emission reduction state of art technology in the marine
field
CHAPTER-9
LNG Carriers
with ME-GI Engine and
High
Pressure Gas Supply System
The demand for larger and more
energy efficient LNG carriers has
resulted in rapidly increasing use of the diesel engine as the prime mover,
replacing traditional steam turbine propulsion plants.
A low speed direct propulsion alternative,
using a dual-fuel two-stroke engine, is now also available:
High
thermal efficiency, flexible fuel/ gas ratio, low operational and installation
costs are the major benefits of this
alternative engine version
The
engine utilises a high-pressure gas system to supply boil-off gas at pressures
of 250-300 bar for injection into the cylinders.
Apart
from the description of the fuel gas supply system, this paper also
discusses related issues such as
requirements for classification, hazardous identification procedures, main
engine room safety, maintenance requirements and availability.
It
will be demonstrated that the ME-GI based solution has operational and economic
benefits over other low speed based solutions, irrespective of vessel size,
when the predicted criteria for relative energy prices prevail.
ME-GI Gas System
Engineering
The ME-GI engine series, in terms of
engine performance (output, speed, thermal efficiency, exhaust gas amount and
temperature, etc.) is identical to the well-established, type approved ME
engine series. The application potential for the ME engine series therefore
also applies to the ME-GI engine, provided that gas is available as a main
fuel. All ME engines can be offered as ME-GI engines. Since the ME system is
well known, the following description of the ME-GI engine design only deals with new or modified
engine components. Fig. 9 shows one cylinder unit of a S70ME-GI, with detail of
the new modified parts. These comprise gas supply double-wall piping, gas valve
control block with internal accumulator on the (slightly modified) cylinder
cover, gas injection valves and ELGI valve for control of the injected gas
amount. In addition,
there
are small modifications to the exhaust gas receiver, and the control and
manoeuvring system.
Apart from these systems on the engine,
the engine and auxiliaries will comprise some new units. The most important
ones, apart from the gas supply system, are listed below, and the full system
is shown in schematic form in Appendix IV The new units are: Ventilation
system, for venting the space between the inner and outer pipe of the
double-wall piping. Sealing oil system,
delivering sealing oil to the gas valves separating the control oil and the
gas. Inert gas system, which enables purging of the gas system on the engine
with inert gas.
The
GI system also includes:
Control
and safety system, comprising a hydrocarbon analyser for checking the
hydrocarbon content of the air in the double-wall gas pipes.
The
GI control and safety system is designed to “fail to safe condition”. All
failures
detected
during gas fuel running including failures of the control system itself, will
result in a gas fuel Stop/Shut Down, and a change-over to HFO fuel operation.
Blow-out
and gas-freeing purging of the high-pressure gas pipes and the complete gas
supply system follows. The changeover to fuel oil mode is always done without
any power loss on the engine.
The
high-pressure gas from the compressor unit flows through the main pipe via
narrow and fl exible branch pipes to
each cylinder’s gas valve block and accumulator. These branch pipes perform two important tasks:
They
separate each cylinder unit from the rest in terms of gas dynamics, utilizing
the well-proven design philosophy of the
ME engine’s fuel oil system.
They
act as flexible connections between the stiff main pipe system and the engine
structure, safeguarding against
extra-stresses in the main and branch pipes caused by the inevitable
differences in thermal expansion of the gas pipe system and the engine
structure.
The
buffer tank, containing about 20 times the injection amount per stroke at MCR,
also performs two important tasks:
It
supplies the gas amount for injection at a slight, but predetermined, pressure
drop.
It
forms an important part of the safety system.
Since
the gas supply piping is of common rail design, the gas injection valve must be
controlled by an auxiliary control oil system. This, in principle, consists of
the ME hydraulic control (system) oil system and an ELGI valve, supplying
highpressure control oil to the gas injection valve, thereby controlling the
timing and opening of the gas valve.
ME-GI
Injection System
Dual
fuel operation requires the injection of
both pilot fuel and gas fuel into the combustion chamber.
Different
types of valves are used for this purpose. Two are fitted for gas injection and
two for pilot fuel. The auxiliary media required for both fuel and gas
operation are as follows:
High-pressure
gas supply
Fuel
oil supply (pilot oil)
Control
oil supply for activation of gas injection valves
Sealing
oil supply.
The
gas injection valve design is shown in Fig. 10. This valve complies with
traditional design principles of compact
design. Gas is admitted to the gas injection valve through bores in the
cylinder cover. To prevent gas leakage between cylinder cover/gas
injection valve and valve
housing/spindle guide, sealing rings made of temperature and
gas
resistant material are installed. Any gas leakage through the gas sealing rings will be led through bores in the gas injection valve and further to space
between the inner and the outer shield
pipe of the double-wall gas piping system. This leakage will be detected
by HC sensors.
The
gas acts continuously on the valve spindle at a max. pressure of about 250 bar.
To prevent gas from entering the control
oil activating system via the clearance around the spindle, the spindle is sealed by sealing oil
at a pressure higher than the gas pressure
(25-50
bar higher).
The
pilot oil valve is a standard ME fuel
oil valve without any changes, except for the nozzle. The fuel oil
pressure is constantly monitored by the GI safety system, in order to detect
any malfunctioning of the valve.
Fig.
10: Gas injection valve – ME-GI engine
The
designs of oil valve will allow operation solely on fuel oil up to MCR. lf the
customer’s demand is for the gas engine to run at any time at 100 % load on
fuel oil, without stopping the engine, this can be done. If the demand is prolonged
operation on fuel oil, it is recommended to change the nozzles and gain an
increase in effi ciency of around 1%
when running at full engine load.
Fig.
11: ME-GI system
As
can be seen in Fig. 11 (GI injection system), the ME-GI injection system
consists of two fuel oil valves, two fuel gas valves, ELGI for opening and
closing of the fuel gas valves, and a FIVA valve to control (via the fuel oil
valve) the injected fuel oil profi le. Furthermore, it consists of the
conventional fuel oil pressure booster, which supplies pilot oil in the dual
fuel operation mode. This fuel oil pressure booster is equipped
with
a pressure sensor to measure the pilot oil on the high pressure side. As
mentioned earlier, this sensor monitors the functioning of the fuel oil valve.
If any deviation from a normal injection is found, the GI safety system will
not allow opening for the control oil via the ELGI valve. In this event no gas
injection will take place.
Under
normal operation where no malfunctioning of the fuel oil valve is found, the
fuel gas valve is opened at the correct crank angle position, and gas is
injected. The gas is supplied directly into an ongoing combustion. Consequently
the chance of having unburnt gas eventually slipping past the piston rings and
into the scavenge air receiver
is
considered to be very low. Monitoring the scavenge air receiver pressure
safeguards
against
such a situation. In the event of high pressure, the gas mode is stopped and
the engine returns to burning fuel oil only.
The
gas flow to each cylinder during one cycle will be detected by measuring the
pressure drop in the accumulator. By this system, any abnormal gas flow,
whether due to seized gas injection valves or blocked gas valves, will be
detected immediately. The gas supply will be discontinued and the gas lines
purged with inert gas. Also in this
event,
the engine will continue running on fuel oil only without any power loss.
High-Pressure
Double-Wall Piping
A
common rail (constant pressure) gas supply system is to be fitted for high
pressure
gas
distribution to each valve block. Gas pipes are designed with double-walls,
with the outer shielding pipe designed so as to prevent gas outflow to the
machinery spaces in the event of rupture of the inner gas pipe.
The
intervening space, including also the space around valves, flanges, etc., is
equipped with separate mech-anical ventilation with a capacity of approx. 30
air changes per hour. The pressure in the intervening space is below that of
the engine room with the (extractor) fan motors placed outside the ventilation
ducts. The ventilation inlet air is taken from a non-hazardous area.
Gas
pipes are arranged in such a way, see Fig. 12 and Fig 13, that air is sucked
into the double-wall piping system from around the pipe inlet, from there into
the branch pipes to the individual gas valve control blocks, via the branch
supply pipes to the main supply pipe, and via the suction blower into the
atmosphere. Ventilation air is exhausted to a fi re-safe place. The double-wall
piping system is designed so that every part is ventilated.
All
joints connected with sealings to a high-pressure gas volume are being
ventilated. Any gas leakage will therefore be led to the ventilated part of the
double-wall piping system and be detected by the HC sensors.
The
gas pipes on the engine are designed for 50% higher pressure than the normal
working pressure, and are supported so as to avoid mechanical vibrations. The
gas pipes are furthermore shielded against heavy items falling down, and on the
engine side they are placed below the top-gallery. The pipes are pressure
tested at 1.5 times the working pressure. The design is to be all-welded, as
far as it is practicable, using flange connections only to the extent necessary
for servicing purposes.
Fig. 12: Branching of gas piping system
Fig.
13: Gas valve control block
Ventilation air
The branch piping to the individual
cylinders is designed with adequate flexibility to cope with the thermal
expansion of the engine from cold to hot condition. The gas pipe system is also
designed so as to avoid excessive gas pressure fluctuations during operation.
For the purpose of purging the system
after gas use, the gas pipes are connected to an inert gas system with an inert
gas pressure of 4-8 bar. In the event of a gas failure, the high-pressure pipe
system is depressurised before automatic purging. During a normal gas stop, the
automatic purging will be started after a period of 30 min. Time is
therefore
available for a quick re-start in gas mode.
Fuel
Gas System -
Control
Requirements
The primary function of the compressor
control system is to ensure that the required discharge pressure is always
available to match the demand of the main propulsion diesel engines. In doing
so, the control system must adequately handle the gas supply variables such as
tank pressure, BOG rate (laden and ballast voyage), gas composition and gas
suction temperature.
If the amount of nBOG decreases, the
compressor must be operated on part load to ensure a stable tank pressure, or
forced boil-off gas (fBOG) added to the gas supply. If the amount of nBOG
increases, resulting in a higher than acceptable tank pressure, the control
system must act to send excess gas to
the
gas combustion unit (GCU).
Tank pressure changes take place over a
relatively long period of time due to the large storage volumes involved.
A fast reaction time of the control
system is therefore not required for this control variable.
The main control variable for compressor
operation is the feed pressure to the ME-GI engine, which may be subject to
controlled or instantaneous change. An adequate control system must be able to
handle such events as part of the “normal” operating procedure.
The required gas delivery pressure
varies between 150-265 bar, depending on the engine load (see Fig. 14 below).
Fig.
14: Gas supply station, guiding specifi cation
The compressor must also be able to
operate continuously in full recycle mode with 100 % of delivered gas returned
to the suction side of the compressor. In addition, simultaneous delivery of
gas to the ME-GI engine and GCU must be possible.
When
considering compressor control, an important difference between centrifugal and
reciprocating compressors should be understood. A reciprocating compressor will
always deliver the pressure demanded by the down-stream user, independent of
any suction conditions such as temperature, pressure, gas composition, etc.
Centrifugal compressors are designed to deliver a certain head of gas for a
given flow. The discharge pressure of these compressors will therefore vary
according to the gas suction condition.
This
aspect is very important when considering transient starting conditions such as
suction temperature and pressure. The 6LP250-5S_1 reciprocating compressor has
a simple and fast startup procedure.
Compressor
control – 6LP250-5S_1 Overall control concept
Fig.
15 shows a simplified view of the compressor process flow sheet. The system may
be effectively divided into a low-pressure section (LP) consisting of the cold
compression stage 1, and a high-pressure section (HP) consisting of stages 2 to
5.
The
main control input for compressor control is the feed pressure P set required
by the ME-GI engine. The feed pressure may be set in the range of 150 to 265
bar according to the desired engine load. If the two ME-GI engines are operating at different loads, the higher set
pressure is valid for the compressor control unit.
If
the amount of nBOG is insufficient to satisfy the engine load requirement, and
make-up with fBOG is not foreseen, the compressor will operate on part load to
ensure that the tank pressure remains
within
specified limits. The ME-GI engine will act independently to increase the
supply of HFO to the engine. Primary regulation of the compressor capacity is
made with the 1st stage bypass valve, followed by cylinder valve unloading and
if required bypass over stages 2 to 5. With this sequence, the compressor is
able to operate flexibly over the full capacity range from 100 to 0 %.
If
the amount of nBOG is higher than can be burnt in the engine (for example
during early part of the laden voyage) resulting in higher than acceptable
suction pressure (tank pressure), the control system will send excess gas to
the GCU via the side stream of the 1st
compression stage.
Fig.
15: Simplified flow sheet
In
the event of engine shutdown or sudden change in engine load, the compressor
delivery line must be protected against overpressure by opening bypass valves
over the HP section of the compressor.
During
start-up of the compressor with warm nBOG, the temperature control valves will
operate to direct a flow through an additional gas intercooler after the 1st
compression stage.
The
control concept for the compressor is based on one main control mode which is
called “power saving mode”. This mode of running, which minimizes the use of
gas bypass as the primary method of regulation, operates within various well
defi ned control limits.
The
system pressure control limits are as follows:
Pmin
suction Prevents
under-pressure in compressor inlet manifold - tank vacuum.
Phigh
suction Suction
manifold high pressure - system safety (GCU) on standby.
Pmax
suction Initiates
action to reduce inlet manifold pressure.
Pmax
Prevents
overpressure of
ME-GI
feed compressor
discharge manifold.
A
detailed description of operation within these control limits is given below.
Power saving mode
Economical regulation of a multi-stage
compressor is most efficiently executed using gas recycle around the 1st stage
of compression. The ME-GI required set pressure Pset is therefore taken as
control input directly to the compressor
1st stage bypass valve, which will open
or close until the actual compressor discharge pressure is equal to the Pset.
With this method of control, BOG delivery to the ME-GI is regulated without any
direct measurement and control of the delivered mass flow. If none of the above
control limits are active, the controller is able to regulate the mass flow in
the range from 0 to 100 %.
The following control limits act to
overrule the ME-GI controller setting and initiate bypass valve operation:
Pmin
suction (tank
pressure below set level)
The
control scenario is falling suction pressure. If the Pmin limit is active, the
1st stage recycle valve will not be permitted to close further,
thereby preventing further reduction in suction pressure. If the pressure in
the suction line continues to decrease, the recycle valve will open governed by
the Pmin limiter.
Action
of Pressure
will fall at the ME-GI control compressor discharge system: requiring
the HFO injection rate to be increased.
fBOG:
If
a spray cooling or forced vaporizer is installed, it may be used for
stabilising the suction pressure and thereby increase the gas mass flow to the
engine. Such a system could be activated by the Pmin suction pressure limit.
Phigh
suction (tank
pressure above set level)
The
control scenario is increasing suction pressure due to either reduced engine
load (e.g. approaching port, manoeuvring) or excess nBOG due to liquid
impurities (e.g. N2).
The
control limiter initiates a manual start of the GCU (the GCU is assumed not to
be on standby mode during normal voyage).
There
is no action on the compressor control or the ME-GI control system.
Pmax
suction (tank
pressure too high)
The
control scenario is the same as described above, however, it has resulted in
even higher suction pressure. Action must now be taken to reduce suction
pressure by sending gas to the GCU.
The
high pressure alarm initiates a manual sequence whereby the 1st
stage bypass valve PCV01 is closed and the bypass valve PCV02 to the GCU is
opened. When the changeover is completed, automatic Pset control is transferred
to the GCU control valve PCV02. The gas amount which cannot
be
accepted by the ME-GI will be
Machinery
Room Installation – 6LP250-5S
The
layout of the cargo handling equipment and the design of their supporting
structure presents quite a challenge to the shipbuilder where space on deck is
always at a premium. In conjunction with HHI and the compressor maker, an
optimised layout of the fuel gas compressor has been developed.
There
are many factors which influence the compressor plant layout apart from limited
space availability. (See Fig. 16.) External piping connections, adequate access
for operation and maintenance, equipment design and manufacturing codes, plant
lifting and installation are just a few.
The
compressor together with accessory items comprising motor drive, auxiliary oil
system, vessels, gas coolers, interconnecting piping, etc., are manufactured as
modules requiring minimum assembly work on the ship deck. Separate auxiliary
systems provide coolant for the compressor frame and gas coolers.
If
required, a dividing bulkhead may separate the main motor drive from the
hazardous area in the compressor room. A compact driveshaft arrangement without
bulkhead, using a suitably designed ex motor, is however preferred.
Platforms
and stairways provide access to the compressor cylinders for valve maintenance.
Piston assemblies are withdrawn vertically through manholes in the roof of the
machinery house (see Fig. 17).
Requirements
for Cargo Machinery Room Support
Structure
Fig.
18 shows details of the compressor base frame footprint and requirement for
support by the ship structure.
Reciprocating
compressors, by nature of movement of their rotating parts, exhibit
out-of-balance forces and moments which must be considered in the design of the
supporting structure for acceptable machinery vibration levels.
As
a boundary condition, the structure underneath the cargo machinery room must
have adequate weight and stiffness to provide a topside vibration level of
(approximately) 1.2 - 1.5 mm/s. Satisfactory vibration levels for compressor
frame and cylinders are 8 and 15 mm/s respectively (values given are rms – root
mean square).
Foundation
deflection due to ship movement must, furthermore, be considered in the design
of the compressor plant to ensure stress-free piping terminations.
Maintenance
requirements - availability/reliability
The
low speed, crosshead type compressor design 6LP250-5S, like the ME-GI diesel
engine, is designed for the life time of the LNG carrier (25 to 30 years or
longer). Routine maintenance is limited purely to periodic checking in the
machinery room.
Maintenance
intervention for dismantling, checking and eventual part replacement is
recommended after
each
8,000 hours of operation. Annual maintenance interventions will normally
require 50-70 hours work for checking and possible replacing of wearing parts.
Major
intervention for dismantling and bearing inspection is recommended every 2-3
years.
Average
availability per compressor unit is estimated to be 98.5 % with best
availability approximately 99.5 %. With an installed redundant unit, the
compressor plant availability will be in the region of 99.25 %.
Any
unscheduled stoppage of the 6LP250-5S compressor will most likely be
attributable to a mal-function of a cylinder valve. With the correct valve
design and material selection (Burckhardt uses its own design and manufacture
plate valves) these events will be very seldom, however a valve failure in
operation cannot be entirely ruled out.
LNG
boil-off gas is an ideal gas to compress.
The gas is relatively pure and uncontaminated, the gas components are
well defined, and the operating temperatures are stable once “cool-down” is
completed.
These
conditions are excellent for long lifetime of the compressor valves where an
average lifetime expectancy for valve plates is 16,000 hours. Therefore, we do
not expect any unscheduled intervention
per
year for valve maintenance. Such a maintenance intervention will take approx.
7-9 hours for compressor shutdown, isolation and valve replacement.
A
total unscheduled maintenance intervention time of 25 hours, assuming 8,000
operating hours per year, may be used for statistical comparison. On this basis
compressor reliability is estimated
at
99.7 %.
Our
experience in many installations shows that no hours are lost for unscheduled
maintenance. The reliability of these compressors is therefore comparable to
that of centrifugal compressor types.
Requirements
for Classification
When
entering the LNG market with the combined two-stroke and reliquefaction
solution, it was discovered that there is a big difference in the requirements
from operators and classification societies.
Being used to cooperating with the classification societies on other commercial
ships, the rules and design recommendations for the various applications in the
LNG market are new when it comes to diesel engine propulsion. In regard to
safety, the high availability and
reliability offered when using the two-stroke engines generally fulfi l the
requirements,
but as the delivery and pick up of gas in the terminals is carried out within a
very narrow time window, redundancy is therefore essential to the operators.
As
such, a two-engine ME-GI solution is the new choice, with its high efficiency,
availability and reliability, as the traditional HFO burning engines.
Compared
with traditional diesel operated ships, the operators and shipowners in the LNG
industry generally have different goals and demands to their LNG tankers, and
they often apply more strict design
criteria than applied so far by the classification societies.
A
Hazid investigation was therefore found
to be the only way to secure that all situations are taken into account when
using gas for propulsion, and that all necessary precautions have been taken to
minimize any risk involved.
In
2005, HHI shipyard, HHI engine builder, BCA and MAN Diesel therefore worked out
a hazard identifi cation study that was conducted by Det Norske Veritas (DNV),
see Appendix V.
Actual
Test and Analysis of Safety when Operatingon Gas
The use of gas on a diesel engine calls
for careful attention with regard to safety. For this reason, ventilated double
walled piping is a minimum requirement to the transportation of gas to the engine.
In addition to hazard
considerations and calculations, it has
been necessary to carry out tests, two of which were carried out some years ago
before the installation and operation of the Chiba power plant 12K80MC-GI
engine in 1994.
A
crack in the double-wall inner pipe
The
first test was performed by introducing a crack in the inner pipe to see if the
outer pipe would stay intact. The test
showed no penetration of the outer pipe, thus it could be concluded that the
double-wall concept lived up to the
expectations.
Pressure
fluctuation
The
second test was carried out to investigate the pressure fluctuations in the
relatively long piping from the gas
compressor to the engine. By estimation of the necessary buffer volume in the
piping system, the stroke and injection of gas was calculated to see when safe
pressure fluctuations are achieved within given limits for optimal performance
of the engines. The piping system has been designed on the basis of these
calculations.
Main
Engine Room Safety
The
latest investigation, which was recently finished, was initiated by a number of
players in the LNG market questioning the use of 250 bar gas in the engine
room, which is also located under the wheel house where the crew is working and
living.
Even
though the risk of full breakage happening is considered close to negligible
and, in spite of the precautions introduced in the system design, MAN Diesel
found it necessary to investigate the effect of such an accident, as the
question still remains in part of
the
industry: what if a double-wall pipe breaks in two and gas is released from a
full opening and is ignited?
As
specialists in the offshore industry, DNV were commissioned to simulate such a
worst case situation, study the consequences, and point to the appropriate
countermeasures. DNV’s work comprised a CFD (computational fluid dynamics) imulation of the hazard of an explosion and
subsequent fire, and an investigation of the risk of this situation ever
occurring and at what scale.
As
input for the simulation, the volume of the engine room space, the position of
major components, the air ventilation
rate, and the location of the gas pipe and control room were the key
input parameters.
Realistic
gas leakage scenarios were defined, assuming a full breakage of the outer pipe
and a large or small hole in the inner fuel pipe. Actions from the closure of
the gas shutdown valves, the ventilation system and the ventilation conditions
prior to and after detection are included in the analysis. The amount of gas in
the fuel pipe limits the
duration
of the leak. Ignition of a leak causing
an explosion or a fire is furthermore factored in, due to possible hotspots or
electrical equipment that can give sparks in the engine room.
Calculations
of the leak rate as a function of time, and the ventilation flow rates were
performed and applied as input to the explosion and fire analyses
Simulation
Results
The
probability of this hazard happening is based on experience from the offshore
industry.
Even
calculated in the worst case, no structural damage will occur in the HHI LNG
engine room if designed for 1.1bar over pressure.
No
areas outside the engine room will be affected by an explosion. If this
situation is considered to represent
too
high a risk, unattended machinery space during gas operation can be introduced.
Today, most engines and equipment are already approved by the classification
societies for this type of operation.
By
insulation, the switchboard room floor can be protected against heat from any
jet fires.
No
failure of the fuel oil tank structure, consequently no escalation of fire. The
above conclusion is made on the assumption that the GI safety system is fully
working. In addition,
DNV
has arrived at a different result based on the assumption that the safety
system is not working. Onthe basic in these results DNV have put up failure
frequencies and developed a set of requirements to be followed in case a higher
level of safety is required.
After
these conclusion made by DNV,HHI has developed a level for their engine room
safety that satisfies the requirements from the classification societies, and
also the requirements that are expected from the shipowners.
This
new engine room design is based on the experience achieved by HHI with their
first orders for LNG carriers equipped with 2 x 6S70ME-C and reliquefaction
plant. The extra safety that will be included is listed below:
Double-wall
piping is located as far away as possible from critical walls such as the fuel
tank walls and switchboard room walls. In case of an engine room fire
alarm, a gas shutdown signal is sent
out, the engine room ventilation fans stops, and the air inlet canals are
blocked.
During
gas running it is not possible to perform any heavy lifting with the engine
room crane. A failure of the engine room ventilation will result in a gas
shutdown. HC sensors are placed in the engine room, and their position will be
based on a dispersion analysis made for the purpose of finding the best
location for the sensors.
The
double-wall piping is designed with lyres, so that variation in temperatures
from pipes to surroundings can be absorbed in the piping. In fact, any level of
safety can be
achieved
on request of the shipowner The safety
level request will be achieved in a co-operation between the yard HHI, the
engine builder HHI, the classification society and MAN Diesel A/S.
The
report “Dual fuel Concept: Analysis of fires and explosions in engine room” was
made by DNV consulting and can be ordered by contacting MAN Diesel A/S, in
Copenhagen.
Engine
Operating Modes
One
of the advantages of the ME-GI engine is its fuel flexibility, from which an
LNG carrier can certainly benefi t. Burning the boil-off gas with a variation
in the heat value is perfect for the diesel working principle. At the start of
a laden voyage, the natural boil-off gas holds a large amount of nitrogen and
the
heat value is low. If the boil-off gas is being forced, it can consist of both
ethane and propane, and the heat value could be high. A two-stroke,
high-pressure gas injection engine is able to burn those different fuels and
also without a drop in the thermal effi ciency of the engine. The control
concept comprises
two
different fuel modes, see also Fig. 19.
fuel-oil-only mode minimum-fuel mode
The
fuel-oil-only mode is well known from the ME engine. Operating the engine in
this mode can only be done on fuel oil. In this mode, the engine is considered
“gas safe”. If a failure in the gas system occurs it will result in a gas
shutdown and a return to the fuel-oilonly mode and the engine is “gas safe”.
The
minimum-fuel mode is developed for gas operation, and it can only be started
manually by an operator on the Gas Main
Operating Panel in the control room. In this mode, the control system
will
allow any ratio between fuel oil and gas fuel, with a minimum preset amount of
fuel oil to be used.
The
preset minimum amount of fuel oil, hereafter named pilot oil, to be used is in
between 5-8% depending on the fuel oil quality. Both heavy fuel oil and marine
diesel oil can be used as pilot oil. The min. pilot oil percentage is
calculated from 100% engine load, and is constant in the load range from 30-
100%.
Below 30% load MAN Diesel is not able to guarantee a stable gas and pilot oil
combustion, when the engine reach this lower limit the engine returns to
Fuel-oil-only mode.
Gas
fuels correspond to low-sulphur fuels, and for this type of fuel we recommend
the cylinder lube oil TBN40 to be used. Very good cylinder condition with this
lube oil was achieved from the gas engine on the Chiba power plant.
A
heavy fuel oil with a high sulphur content requires the cylinder lube oil TBN
70. Shipowners intending to run their engine on high-sulphur fuels for longer
periods of time are recommended to install two lube oil tanks. When changing to
minimum-fuel mode, the change of lube oil should be carried out as well.
Players
in the market have been focused on reducing the exhaust emissions during harbour
manoeuvring. When testing the ME-GI at the MAN Diesel research centre in
Copenhagen, the 30% limit for minimum-fuel mode will be challenged taking
advantage of the increased possibilities of the ME fuel
valves
system to change its injection profi le, MAN Diesel expects to lower this 30%
load limit for gas use, but for now no guaranties can be given.
Fig.
19: Fuel type modes for the ME-GI engines for LNG carriers
Launching
the ME-GI
As
a licensor, MAN Diesel expects a time frame of two years from order to delivery
of the first ME-GI on the test bed.
In
the course of this time, depending on the ME-GI engine size chosen, the engine
builder will make the detailed designs and a final commissioning test on a
research engine. This type approval test (TAT) is to be presented to the
classification society and ship owner in question to show that the compressor
and the ME-GI engine is working in all the operation modes and conditions.
In
cooperation with the classification society and engine builder, the most
optimum solution, i.e. to test the
compressor and ME-GI engine before delivery to the operator has been
considered and discussed. One solution
is to test the gas engine on the test
bed, but this is a costly method. Alternatively, and recommended by MAN Diesel,
the compressor and ME-GI operation test could be made in continuation of the gas trial. Today, there are different
opinions among the classification societies, and both solutions are possible
depending on the choice of classification society and arrangement between ship
owners, yard and engine builder.
MAN
Diesel A/S has developed a test philosophy especially for approval of the ME-GI
application to LNG carriers, this philosophy has so far been approved by DNV,
GL, LR and ABS, see Table III. The idea is that the FAT (Factory Acceptance
Test) is being performed for the ME
system like normal, and for the GI system it is performed on board the
LNG
carrier as a part of the Gas Trial Test. Thereby, the GI system is tested in
combination with the tailor-madegas compressor system for the specific LNG
carrier. Only in this combination it will be possible to get a valid test.
Prior
to the gas trial test, the GI system has been tested to ensure that everything
is
working satisfactory
CHAPTER-10
ME-GI Engines
for LNG Application
System Control
and Safety
For these plants, the
boil-off gas is returned to the LNG tanks in liquefied form via
a reliquefaction plant
installed on board.
Some operators are
considering an alternative two-stroke solution, which is the
ME-GI (Gas Injection)
engine operating at a 250-300 bar gas pressure.
Which solution is
optimal for a given project depends primarily on the price of HFO and the value
of natural gas.
Calculations carried
out by MBD sow that additional USD 3 million can be secured as profit per year
when using two-stroke diesel engines, irrespective of whether the HFO or the
dual fuel engine type is chosen. When it comes to first cost, the HFO diesel
engine combined with a reliquefaction plant has the same cost level as the
steam turbine solution, whereas the dual fuel ME-GI engine with a compressor is
a cheaper solution.
This paper will
describe the application of ME-GI engines inclusive the gas supply system on a
LNG carriers, and the layout and control system for both the
engine and gas supply
system.
First, a short
description is given of the propulsion power requirement of LNG
carriers, and why the
two-stroke diesel engine is winning in this market.
Propulsion power
requirements for LNG carriers
Traditionally, LNG
carriers have been sized to carry 130,000 – 140,000 m3 liquefied natural gas,
i.e. with a carrying capacity of some 70-80,000 tons, which resembles that of a
panamax bulk carrier.
The speed has been
around 20 knots, whereas that of the panamax bulk carriers is around 15. Now,
even larger LNG carriers are in project up to a capacity of some 250,000 m3
LNG. Such ships will be comparable in size to a capsize bulk carrier and an
aframax tanker but, again, with a speed higher than these.
In an analysis of the
resulting power requirements, a calculation programme normally used by MBD has
been used, Ref. [2].
The result appears in
Fig. 1, which shows that a power requirement of 30 to 50 MW is needed.
Fig. 1: Typical
propulsion power requirements for LNG carriers
Fig. 2: Typical thermal
efficiencies of prime movers
As mentioned, diesels
are now being seen as an alternative to steam, first of all because of the
significant difference in thermal efficiency reflected also in the system
efficiency, as illustrated in Fig. 2.
With a power
requirement of the mentioned magnitude, the illustrated efficiency difference
of up to 20 percentage points amounts
to significant savings both in terms of energy costs and in terms of emissions.
The desired power for
propulsion can be generated by a single, double, or multiple fuel or gas driven
diesel engine installation with either direct geared or diesel-electric drive
of one or two propellers. The choice depends on economical and operational
factors. Over time, the evaluation of these factors for the options of propulsion
technology, for ordinary larger cargo vessels (viz. container vessels, bulk
carriers and tankers), has led to the selection of a single,
heavy-fuel-burning, low speed diesel engine in more than 90% of contemporary
vessels.
The aim of this paper is
to demonstrate that low speed propulsion is fully feasible for LNG carriers.
Boil-off Gas from LNG
Cargo
The reason for having a
continuous evaporated rate of boil-off gas is that it is generated by heat
transferred from the ambient temperature through the LNG tanks and into to cold
LNG. The boil-off gas is the consequence if the LNG cargo should be staying
liquid at atmospheric pressure and at a temperature of some minus 160 degrees
Celsius. To keep the evaporated rate of boil-off at a minimised level, the
cargo is kept in proper insulated tanks.
The LNG is a mixture of
methane, ethane and nitrogen. Other natural gases like butane and propane are
extracted during the liquefying and are only present in very small quantities.
In a traditional steam turbine vessel, the
boil-off gas is conveniently sent to twin boilers to produce steam for the
propulsion turbine. Due to the proper insulation, the boil-off is usually not
enough to provide the energy needed for propulsion, so the evaporated gas is
supplemented by either forced boil off of gas or heavy fuel oil to produce the
required steam amount.
In a diesel engine
driven LNG carrier, the energy requirement is less thanks to the higher thermal
efficiency, so the supplementary energy by forced boil off or heavy fuel oil
can be reduced significantly, as shown in Fig. 3
Fig. 3: Propulsion alternative – energy
need for propulsion
Fig.
4: Fuel Type Modes – MAN B&W two-stroke dual fuel low speed diesel
Design of the Dual Fuel
ME-GI Engine
In terms of engine performance
(i.e.: output, speed, thermal efficiency, exhaust gas amount and temperature,
etc.) the ME-GI engine series is generally identical to the well-established
and type approved ME engine series. This means that the application potential
for the ME-engine series applies to the ME-GI engine series as well – provided
that gas is available as a main fuel. All ME engines can be offered as ME-GI
engines.
Consequently, the
following description of the ME-GI engine design only deals with new or
modified engine components with the different fuel mode types, as illustrated
in Fig. 4.The control system will allow any ratio between fuel and gas, with a
preset minimum fuel amount to be used.
Fig.6:
General arrangement of double-wall piping system for gas
General Description
Fig.
5 shows the cross-section of a S70ME-GI, with the new modified parts of the
ME-GI engine pointed out, comprising gas supply piping, large-volume
accumulator on the (slightly modified) cylinder cover with gas injection
valves, and HCU with ELGI valve for control of the injected gas amount. Further
to this, there are small modifications to the exhaust gas receiver, and the
control and manoeuvring system.
Apart from these
systems on the engine, the engine auxiliaries will comprise some new units, the
most important ones being:
Fig. 5: New modified parts on the ME-GI
engine
•
High-pressure gas compressor supply system, including a cooler, to raise the
pressure to 250-300 bar, which is the pressure required at the engine inlet.
• Pulsation/buffer tank
including a condensate separator.
• Compressor control
system.
•
Safety systems, which ex. includes a hydrocarbon analyser for checking the
hydro-carbon content of the air in the compressor room and in the double-wall
gas pipes.
• Ventilation system,
which ventilates the outer pipe of the double-wall piping completely.
• Sealing oil system,
delivering sealing oil to the gas valves separating the control oil and the
gas.
• Inert gas system,
which enables purging of the gas system on the engine with inert gas.
Fig. 6, in schematic
form, shows the system layout of the engine. The high pressure gas from the
compressor-unit flows through the main pipe via narrow and flexible branch
pipes to each cylinder’s gas valve block
and large-volume accumulator. The narrow
and flexible branch pipes perform two important tasks:
• They separate each
cylinder unit from the rest in terms of gas dynamics, utilizing the well-
proven design philosophy of the ME engine’s fuel oil system.
• They act as flexible
connections between the stiff main pipe system and the engine structure,
safeguarding against extra-stresses in the main and branch pipes caused by the
inevitable differences in thermal expansion of the gas pipe system and the engine
structure.
Fig. 7: ME-GI fuel injection system
The large-volume
accumulator, containing about 20 times the injection amount per stroke at MCR,
also performs two important tasks:
• It supplies the gas
amount for injection at only a slight, but predetermined, pressure drop.
• It forms an important
part of the safety system (as described later).
Since the gas supply
system is a common rail system, the gas injection valve must be controlled by
another system, i.e. the control oil system. This, in principle, consists of
the ME hydraulic control (servo) oil system and an ELGI valve, supplying
high-pressure control oil to the gas injection valve, thereby control-ling the
timing and opening of the gas valve.
As can also be seen in
Fig. 7, the normal fuel oil pressure booster, which supplies pilot oil in the
dual fuel operation mode, is connected to the ELGI valve by a pressure gauge
and an on/ off valve incorporated in the ELGI valve.
By the control system,
the engine can be operated in the various relevant modes: normal “dual-fuel
mode” with minimum pilot oil amount, “specified gas mode” with injection of a
fixed gas amount, and the “fuel-oil-only mode”.
The ME-GI control and
safety system is built as an add-on system to the ME control and safety system.
It hardly requires any changes to the ME system, and it is consequently very
simple to implement.
The principle of the
gas mode control system is that it is controlled by the error between the
wanted discharge pressure and the actual measured discharge pressure from the
compressor
system. Depending on
the size of this error the amount of fuel-gas (or of pilot oil) is either
increased or decreased.
If there is any
variation over time in the calorific value of the fuel-gas it can be measured
on the rpm of the crankshaft. Depending on the value measured, the amount of
fuel-gas is either increased or decreased.
The change in the
calorific value over time is slow in relation to the rpm of the engine.
Therefore the required change of gas amount between injections is relatively
small.
To make the engine easy
to integrate with different suppliers of external gas delivering systems, the
fuel gas control system is made almost “stand alone”. The exchanged signals are
limited to top, Go, ESD, and pressure set-point signals.
Fig. 8: Engine control system diagram
System description
Compared with a
standard engine for heavy fuel operation, the adaptation to high-pressure gas
injection requires that the design of the engine and the pertaining external
systems will comprise a number of special external components and changes on
the engine.
Fig. 9 shows the
principal layout of the gas system on the engine and some of the external
systems needed for dual fuel operation.In general, all systems and components
described in the following are to be made “fail safe”, meaning that components and systems will
react to the safe side if anything goes wrong.
Fig. 9: Internal and external systems
for dual fuel operation
Engine systems
In
the following, the changes of the systems/ components on the engine, as pointed
out in Fig. 5, will be described.
Exhaust receiver
The
exhaust gas receiver is designed to withstand the pressure in the event of
ignition failure of one cylinder followed by ignition of the unburned gas in
the receiver (around 15 bars).
The receiver is
furthermore designed with special transverse stays to withstand such gas
explosions.
Fuel injection valves
Dual fuel operation
requires valves for both the injection of pilot fuel and gas fuel.
The valves are of
separate types, and two are fitted for gas injection and two for pilot fuel.
The media required for both fuel and gas operation is shown below:
• High-pressure gas
supply
• Fuel oil supply
(pilot oil)
• Control oil supply
for activation
of
gas injection valves
• Sealing oil supply.
The gas injection valve
design is shown in Fig. 10.
Fig. 10: Gas injection valve
This valve complies
with our traditional design principles of compact design and the use of mainly
rotational symmetrical parts. The design is based on the principle used for an
early version of a combined fuel oil/gas injection valve as well as experience
gained with our normal fuel valves.
Gas is admitted to the
gas injection valve through bores in the cylinder cover. To prevent gas leakage
between cylinder cover/gas injection valve and valve housing/spindle guide,
sealing rings made of temperature and gas resistant material are installed. Any
gas leakage through the gas sealing rings will be led through bores in the gas
injection valve and the cylinder cover to the double-wall gas piping system,
where any such leakages will be detected by HC sensors.
The gas acts
continuously on the valve spindle at a pressure of about 250-300 bar. In order
to prevent the gas from entering the control oil activating system via the clearance
around the spindle, the spindle is sealed by means of sealing oil led to the
spindle clearance at a pressure higher than the gas pressure (25-50 bar
higher).
The pilot valve is a
standard fuel valve without any changes.
Both designs of gas injection
valves will allow operation solely on fuel oil up to MCR. lf the customer’s
demand is for the gas engine to run at any time at 100 % load on fuel oil,
without stopping the engine for changing the injection equipment, the fuel
valve nozzle holes will be as the standard type for normal fuel oil operation.
In this case, it may be necessary to use a somewhat larger amount of pilot fuel
in order to assure a good injection quality and safe ignition of the gas.
Cylinder cover
In order to protect the
gas injection nozzle and the pilot oil nozzle against tip burning, the cylinder
cover is designed with a welded-on protective guard in front of the nozzles.
The side of the
cylinder cover facing the HCU (Hydraulic Cylinder Unit) block has a face for
the mounting of a special valve block, see later description.
In addition, the
cylinder cover is provided with two sets of bores, one set for supplying gas
from the valve block to each gas injection valve, and one set for leading any
leakage of gas to the sub-atmo-Fig. 9: Internal and external systems for
dual fuel operation spheric pressure, ventilated part of the double-wall
piping system.
Hydraulic Cylinder Unit
(HCU)
To reduce the number of
additional hydraulic pipes and connections, the ELGI valve as well as the
control oil pipe connections to the gas valves will be incorporated in the
design of the HCU.
Valve block
The valve block
consists of a square steel block, bolted to the HCU side of the cylinder cover.
The valve block
incorporates a large volume accumulator, and is provided with a shutdown valve
and two purge valves on the top of the block. All highpressure gas sealings
lead into spaces that are connected to the double-wall pipe system, for leakage
detection.
The gas is supplied to
the accumulator via a non-return valve placed in the accumulator inlet cover.
To ensure that the rate
of gas flow does not drop too much during the injection period, the relative
pressure drop in the accumulator is measured. The pressure drop should not
exceed about 20-30 bar.
Any larger pressure
drop would indicate a severe leakage in the gas injection valve seats or a
fractured gas pipe. The safety system will detect this and shut down the gas
injection.
From the accumulator,
the gas passes through a bore in the valve block to the shut down valve, which
in the gas mode, is kept open by compressed air. From the shutdown valve (V4 in
Fig. 9), the gas is led to the gas injection valve via bores in the valve block
and in the cylinder cover.
A blow-off valve (V3 in
Fig. 9), placed on top of the valve block, is designed to empty the gas bores
when needed.
A purge valve (V5 shown
in Fig. 9), which is also placed on top of the valve block, is designed to
empty the accumulator when the engine is no longer to operate in the gas mode.
Gas pipes
A common rail (constant
pressure) system is to be fitted for high-pressure gas distribution to each
valve block.
Gas pipes are designed
with double walls, with the outer shielding pipe designed so as to prevent gas
outflow to the machinery spaces in the event of rupture of the inner gas pipe.
The intervening space, including also the space around valves, flanges, etc.,
is equipped with separate mechanical
ventilation with a capacity of approx. 10 – 30 air changes per hour. The
pressure in the intervening space is to
be below that of the engine room and, as mentioned earlier, (extractor) fan
motors are to be placed outside the ventilation ducts, and the fan material
must be manufactured from spark-free material. The ventilation inlet air must
be taken from a gas safe area.
Gas pipes are arranged
in such a way, see Fig. 6, that air is sucked into the double-wall piping
system from around the pipe inlet, from there into the branch pipes to the
individual cylinder blocks, via the branch supply pipes to the main supply
pipe, and via the suction blower to the atmosphere. Ventilation air is to be
exhausted to a safe place.
The double-wall piping
system is designed so that every part is ventilated. however, minute volumes
around the gas injection valves in the cylinder cover are not ventilated by
flowing air for practical reasons. Small gas amounts, which in case of leakages
may accumulate in these small clearances, blind ends, etc. cannot be avoided,
but the amount of gas will be negligible. Any other leakage gas will be led to
the ventilated part of the double-wall piping system and be detected by the HC
sensors.
The gas pipes on the
engine are designed for 50 % higher pressure than the normal working pressure,
and are supported so as to avoid mechanical vibrations.
The gas pipes should
furthermore be protected against drops of heavy items. The pipes will be
pressure tested at 1.5 times the working pressure. The design is to be
all-welded as far as practicable, with flange connections only to the necessary
extent for servicing purposes.
The branch piping to
the individual cylinders must be flexible enough to cope with the thermal
expansion of the engine from cold to hot condition.
The gas pipe system is
also to be designed so as to avoid excessive gas pressure fluctuations during
operation. Finally, the gas pipes are to be connected to an inert gas purging
system.
Fuel oil booster system
Dual fuel operation
requires a fuel oil pressure booster, a position sensor, a FIVA valve to
control the injection of pilot oil, and an ELGI valve to control the injection
of gas. Fig. 7 shows the design control principle with the two fuel valves and
two gas valves.
No change is made to
the ME fuel oil pressure booster, except that a pressure sensor is added for
checking the pilot oil injection pressure. The injected amount of pilot oil is
monitored by the position sensor.
The injected gas amount
is controlled by the duration of control oil delivery from the ELGI valve. The
operating medium is the same servo oil as is used for the fuel oil pressure
booster.
Miscellaneous
Other engine
modifications will, basically, be limited to a changed position of pipes,
platform cut-outs, drains, etc.
Safety aspects
The normal safety
systems incorporated in the fuel oil systems are fully retained also during
dual fuel operation. However, additional safety devices will be incorporated in
order to prevent situations which might otherwise lead to failures.
Safety devices –
External systems
Leaky valves and
fractured pipes are sources of faults that may be harmful. Such faults can be
easily and quickly detected by a hydro-carbon (HC) analyzer with an alarm
function. An alarm is given at a gas concentration of max. 30% of the Lower
Explosion Limit (LEL) in the vented duct, and a shut down signal is given at
60% of the LEL.
The safety devices that
will virtually eliminate such risks are double-wall pipes and encapsulated
valves with ventilation of the intervening space. The ventilation between the
outer and inner walls is always to be in operation when there is gas in the
supply line, and any gas leakage will be led to the HC-sensors placed in the
outer pipe.
Another source of fault
could be a malfunctioning sealing oil supply system. If the sealing oil pressure becomes too low in the gas injection
valve, gas will flow into the control oil activation system and, thereby,
create gas pockets and prevent the ELGI valve from operating the gas injection
valve. Therefore, the sealing oil pressure is measured by a set of pressure
sensors, and in the event of a too low pressure, the engine will shut down the
gas mode and start running in the fuel oil mode.
Lack of ventilation in
the double-wall piping system prevents the safety function of the HC sensors, so the system is to be equipped with
a set of flow switches. If the switches indicate no flow, or nearly no flow, an
alarm is given. If no correction is carried out, the engine will be shut down
on gas mode. The switches should be of the normally open (NO) type, in order to
allow detection of a malfunctioning switch, even in case of an electric power
failure.
•
In case of malfunctioning valves (not leaky) resulting in insufficient gas
supply to the engine, the gas pressure will be too low for gas operation. This
is dealt with by monitoring the pressure in the accumulator in the valve block
on each cylinder. The pressure could be monitored by either one pressure
pick-up, or by a pressure switch and a differential pressure switch (see later
for explanation).
As natural gas is
lighter than air, non-return valves are incorporated in the gas system’s outlet
pipes to ensure that the gas system is not polluted, i.e. mixed with air, thus
eliminating the potential risk of explosion in case of a sudden pressure
increase in the system due to quick opening of the main gas valve.
For LNG carriers in
case of too low a BOG pressure in the LNG tanks, a stop/off signal is sent to
the ME-GI control system and the gas mode is stopped, while the engine
continues running on HFO.
Safety devices –
Internal systems
During normal operation,
a malfunction in the pilot fuel injection system or gas injection system may
involve a risk of uncontrolled combustion in the engine.
Sources of faults are:
•
Defective gas injection valves
•
Failing ignition of injected gas
These aspects will be
discussed in detail in the following together with the suitable counter
measures.
Defective gas injection
valves
In case of sluggish
operation or even seizure of the gas valve spindle in the open position, larger
gas quantities may be injected into the cylinder, and when the exhaust valve
opens, a hot mixture of combustion products and gas flows out and into the
exhaust pipe and further on to the exhaust receiver. The temperature of the
mixture after the valve will increase considerably, and it is likely that the
gas will burn with a diffusion type flame (without exploding) immediately after
the valve where it is mixed with scavenge air/exhaust gas (with approx. 15 per
cent oxygen) in the exhaust system. This will set off the high exhaust gas
temperature alarm for the cylinder in question. In the unlikely event of larger
gas amounts entering the exhaust receiver without starting to burn immediately,
a later ignition may result in violent burning and a corresponding pressure
rise. Therefore, the exhaust receiver is designed for the maximum pressure
(around 15 bars).
However, any of the
above-mentioned situations will be prevented by the detection of defective gas
valves, which are arranged as follows:
The gas flow to each
cylinder during one cycle will be detected by measuring the pressure drop in
the accumulator. This is to ensure that the injected gas amount does not exceed
the amount corresponding to the MCR value.
It is necessary to
ensure that the pressure in the accumulator is sufficient for gas operation, so
the accumulator will be equipped with a pressure switch and a differential
pressure switch. An increase of the gas flow to the cylinder which is greater
than corresponding to the actual load, but smaller than corresponding to the
MCR value, will only give rise to the above-mentioned exhaust gas temperature
alarm, and is not harmful.
By this system, any
abnormal gas flow, whether due to seized gas injection valves or fractured gas
pipes, will be detected immediately, and the gas supply will be discontinued
and the gas lines purged with inert gas.
In the case of slightly
leaking gas valves, the amount of gas injected into the cylinder concerned will
increase. This will be detected when the exhaust gas temperature increases.
Burning in the exhaust receiver will not occur in this situation due to the
lean mixture.
Ignition failure of
injected gas
Failing ignition of the
injected natural gas can have a number of different causes, most of which,
however, are the result of failure to inject pilot oil in a cylinder:
•
Leaky joints or fractured high-pressure pipes, making the fuel oil booster
inoperative.
•
Seized plunger in the fuel oil booster.
•
Other faults on the engine, forcing the
fuel
oil booster to “O-index”.
•
Failing pilot oil supply to the engine.
Any such faults will be
detected so quickly that the gas injection is stopped immediately from the
first failure to inject the pilot oil.
In extremely rare
cases, pilot fuel can be injected without being ignited, namely in the case of
a sticking or severely burned exhaust valve. This may involve such large
leakages that the compression pressure will not be sufficient to ensure
ignition of the pilot oil. Consequently, gas and pilot fuel from that cylinder
will be supplied to the exhaust gas receiver in a fully unburned condition,
which might result in violent burning in the receiver. However, burning of an
exhaust valve is a rather slow process extending over a long period, during
which the exhaust gas temperature rises and gives an alarm well in advance of
any situation leading to risk of misfiring.
A seized spindle in the
pilot oil valve is another very rare fault, which might influence the safety of
the engine in dual fuel operation. However, the still operating valve will
inject pilot oil, which will ignite the corresponding gas injection, and also
the gas injected by the other gas valve, but knocking cannot be ruled out in
this case. The cylinder pressure monitoring system will detect this condition.
As will appear from the
above discussion, which has included a number of very unlikely faults, it is
possible to safeguard the engine installation and personnel and, when taking
the proper countermeasures, a most satisfactory service reliability and safety
margin is obtained.
External systems
The detailed design of
the external systems will normally be carried out by the individual
shipyard/contractor, and is, therefore, not subject to the type approval of the
engine. The external systems de- scribed here include the sealing oil system,
the ventilation system, and the gas supply and compressor system.
Sealing oil system
The sealing oil system
supplies oil, via a piping system with protecting hoses, to the gas injection
valves, thereby providing a sealing between the gas and the control oil, and
lubrication of the moving parts.
The sealing oil pump
has a separate drive and is started before commencing gas operation of the
engine. It uses the 200 bar servo oil, or one bar fuel oil, and pres- surises
it additionally to the operating pressure, which is 25-50 bar higher than the
gas pressure. The consumption is small, corresponding to a sealing oil
consumption of approx. 0.1 g/bhph.
After use, the sealing
oil is burned in the engine.
Fig. 11: Gas system branching
Ventilation system
The purpose of the
ventilation system is to ensure that the outer pipe of the double-wall gas pipe
system is ventilated with air, and it acts as a separation between the engine
room and the high-pressure gas system, see Fig 11. Ventilation is achieved by means
of an electrically driven mechanical fan or extractor fan. If an electrically
driven fan is chosen, the motor must be placed outside the ventilation duct.
The capacity must ensure approx. 10 – 30 air changes per hour. More ventilation
gives quicker detection of any gas leakage. Fig. 12: Gas supply system –
natural BOG only
The gas Compressor
System
The gas supply system
is based on Flotech™ packaged compressors:
§ Low-pressure GE
Oil & Gas RoFlo™ type gas compressors with lubricated vanes and oil buffered
mechanical seals, which compress the cold boil-off gas from the LNG tanks at
the temperature of -140oC to -160oC. The boil-off gas pressure in the LNG tanks
should normally be kept between 1.06-1.20 bar(a). Under normal running
conditions, cooling is not necessary, but during start up, the temperature of
the boil-off gas may have risen to atmospheric temperature, hence pre-heating
and after-cooling is included, to ensure stabilisation of the cold inlet and
intermediate gas. temperature
§
The
high-pressure GE Oil & Gas Nuovo Pignone™ SHMB type gas compressor; 4
throw, 4-stage horizontally opposed and fully balanced crosshead type with
pressure lubricated and water-cooled cylinders & packings, compresses the
gas to approximately 250-300 bar, which is the pressure required at the engine
inlet at full load. Only reciprocating piston compressors are suitable for this
high pressure duty; however the unique GE fully balanced frame layout addresses
concerns about transmitted vibrations and also eliminates the need for heavy
installation structure, as is required with vertical or V-form unbalanced
compressor designs. The discharge temperature is kept at approx. 45oC by the
coolers.
§
Buffer
tank/accumulators are installed to provide smoothing of minor gas pressure
fluctuations in the fuel supply; ± 2 bar is required.
§
Gas
inlet filter/separator with strainer for protection against debris.
§
Discharge
separator after the final stage gas cooler for oil/condensate removal.
§
Compressor
capacity control system ensures that the required gas pressure is in accordance
with the engine load, and that the boil-off gas amount is regulated for cargo
tank pressure control (as described later).
§
The
compressor safety system handles normal start/stop, shutdown and emergency
shutdown commands. The compressor unit includes a process monitoring and fault
indication system. The compressor control system exchanges signals with the
MEGI control system.
§
The
compressor system evaluates the amount of available BOG and reports to the
ME-GI control system.
Fig. 13: Gas supply system– natural and
forced BOG
Redundancy for the gas
supply system is a very important issue. Redundancy in an extreme sense means
two of all components, but the costs are heavy and a lot of space is required
on board the ship. We have worked out a recommendation that reduces the costs
and the requirement for space while ensuring a fully operational ME-GI engine.
The dual fuel engine concept, in its nature, includes redunancy. If the gas
supply system falls out, the engine will run on heavy fuel oil only.
The gas supply system
illustrated in Fig. 12 and 13 are based on a 210,000 M3 LNG carrier, a boil off
rate of 0.12 and equipped with 2 dual fuel engines: 2 x 7S65ME-GI. For other
sizes of LNG carriers the setup will be the same but the % will be changed.
Figs. 12 and 13 show our recommendations for a gas supply system to be used on
LNG carriers, and figure 15 shows the compressor system in more detail.
Depending on whether the ship owner wishes to run on natural BOG only, Fig. 12,
or run on both natural BOG and forced BOG, Fig. 13 is relevant.
Both systems comprise a
double (2 x 100%) set of Low Pressure compressors each with the
capacity to handle 100% of the natural BOG if one falls out (alternatively 3 x
50% may be chosen). Each of these LP compressors can individually feed both the
High Pressure Compressor and the Gas Combustion
Unit. All compressors can run simultaneously, which can be utilised when the
engine is fed with both natural - and forced BOG.
The HP compressor
section is chosen to be a single unit. If this unit falls out then the ME-GI
engine can run on Heavy Fuel Oil, and one of the LP compressors can feed the
GCU.
Typical availability of
these electrically driven Flotech / GE Oil & Gas compressors on natural gas
(LNG) service is 98%, consequently, an extra HP compressor is a high cost to
add for the 2% extra availability.
Gas supply system
–capacity management
The
minimum requirement for the regulation of supply to the ME-GI engine is a
turndown ratio of 3.33 which equals a regulation down to 30% of the maximum
flow (For a twin engine system, the TR is 6.66). Alternatively in accordance
with the requirements of the ship owners
Both the LP and HP
compressor packages have 0 => 100% capacity variation systems, which allows
enormous flexibility and control.
Stable control of cargo
tank pressure is the primary function of the LP compressor control system.
Dynamic capacity variation is achieved by a combination of compressor speed
variation and gas
Fig. 14: Typical HP fuel oil gas
compressor
Fig. 16: Gas compressor system –
indicating capacity control & cooling system
discharge to recycle.
The system is responsible for maintaining the BOG pressure set tank pressure
point within the range of 1,06 – 1,20 bar(a) through 0 100% compressor
capacity.
ð
At full load of the
ME-GI engine on gas, the HP compressor delivers approximately 265 bar whereas
at 50% load, the pressure is reduced to 130-180 bar. The discharge pressure set
points are controlled within ±5%. Compressor speed variation controls the
capacity range of approximately 100 => 50% of volumetric flow. Speed control
is the primary variation; speed control logic is integrated with recycle to
reduce speed/ capacity when the system is recycling
under standby (0%
capacity) or part load conditions.
LP & HP compressor
systems are coordinated such that BOG pressure is safely controlled, whilst
however delivering all available gas at the correct pressure to the ME-GI
engine. Load and availability signals are exchanged between compressor and
engine control systems for this purpose.
Safety aspects
The compressors are
delivered generally in accordance with the API-11P standard (skid-packaged
compressors) and are designed and certified in accordance with relevant
classification society rules.
Maintenance
The gas compressor
system needs an annual overhaul. The overhaul can be performed by the same
engineers who do the maintenance on the main engines. It requires no special
skills apart from what is common knowledge for an engineer.
External systems
External safety systems
should include a gas analyser for checking the hydrocarbon content of the air,
inside the compressor room and fire warning and protection systems.
Safety devices –
Internal systems
The compressors are
protected by a series of Pressure High, Pressure Low, Temperature High,
Vibration High, Liquid Level High/Low,
Compressor RPM High/Low
and Oil Low Flow trips, which will automatically shut down the compressor if
fault conditions are detected by the local control system.
Pressure safety valves
vented to a safe area guard against uncontrolled overpressure of the fuel gas
supply system.
Inert gas system
After running in the
gas mode, the gas system on the engine should be emptied of gas by purging the
gas system with inert gas (N2, CO2),
Dual Fuel Control
System
General
In addition to the
above a special dual fuel control system is being developed to control the
dual-fuel operation when the engine is operating on compressed gaseous fuels.
See fig. 17. The control system is the glue that ties all the dual fuel parts
in the internal and the external system together and makes the engine run in
gas mode.
As mentioned earlier
the system is designed as an add-on system to the original ME control system.
The consequence is that the Bridge panel, the Main Operating Panel (MOP) &
the Local Operating Panel (LOP) will stay unchanged. All operations in gas mode
are therefore performed from the engine room alone.
When the dual fuel
control system is running the existing ME control and alarm system will stay in
full operation.
Mainly for hardware
reasons the control of the dual fuel operation is divided into:
•
Plant control
•
Fuel control
•
Safety Control
Plant control
The
task of the plant control is to handle the switch between the two stable
states:
•
Gas Safe Condition State ( HFO only)
•
Dual-Fuel State
The plant control can
operate all the fuel gas equipment shown in fig. 10. For the plant control to
operate it is required that the Safety Control allows it to work otherwise the
Safety Control will overrule and return to a Gas Safe Condition.
Fuel control
The task of the fuel
control is to determine the fuel gas index and the pilot oil index when running
in the three different modes shown in fig.4.
Safety control
The
task of the safety system is to monitor:
•
All fuel gas equipment and the related auxiliary equipment
•
The existing shut down signal from the ME safety system.
•
The cylinder condition for being in a condition allowing fuel gas to be
injected.
If one of the above
mentioned failures is detected then the Safety Control releases the fuel gas
Shut Down sequence below:
The Shut down valve V4
and the master valve V1 will be closed. The ELGI valves will be disabled. The
fuel gas will be blow out by opening valve V2 and finally the gas pipe system
will be purged with inert gas. See also fig. 9
Architecture of the
Dual Fuel Control System
Dual Fuel running is
not essential for the manoeuvrability of the ship as the engine will continue
to run on fuel oil if an unintended fuel gas stop occurs. The two fundamental
architectural and design demands of the fuel gas Equipment are, in order of
priority:
•
Safety to personnel must be at least on the same level as for a conventional
diesel engine
•
A fault in the Dual Fuel equipment must cause stop of gas operation and change
over to Gas Safe Condition. Which to some extent complement each other.
The Dual Fuel Control
System is designed to “fail to safe condition”. See Fig. 18. All failures
detected during fuel gas running and failures of the control system itself will
result in a fuel gas Stop / Shut Down and change over to fuel operation. Followed by blow out and purging of high
pressure fuel gas pipes which releases all gas from the entire gas supply
system.
If the failure relates
to the purging system it may be necessary to carry out purging manually before
an engine repair is carried out. (This will be explained later).
The Dual Fuel Control
system is a single system without manual back-up control. However, the
following equipment is made redundant to secure that a single fault will not
cause fuel gas stop:
•
The communication network is doubled in order to minimize the risk of
interrupting the communication between
the control units.
• Vital sensors are
doubled and one set of these sensors is connected to the Plant Control and the
other to the Safety System. Consequently a sensor failure which is not
detectable is of no consequence for safe fuel gas operation.
Control Unit Hardware
For the Dual Fuel
Control System two different types of hardware are used: the Multi Purpose Controller Units and
the GCSU , both developed by MAN B&W Diesel A/S.
The Multi Purpose
Controller Units are used for the following units: GECU, GACU, GCCU, and the
GSSU see also fig. 17. In the following a functionality description for each
units shown in fig. 17
Fig. 17: ME-GI Control System
Gas Main Operating
Panel (GMOP)
For the GI control
system an extra panel called GMOP is introduced. From here all manually
operations can be initiated. For example the change between the different
running modes can be done and the operator has the possibility to manually
initiate the purging of the gas pipes system with inert gas.
Additionally it
contains the facilities to manually start up or to stop on fuel gas.
GECU, Plants control
The GECU handles the
Plant Control and in combination with GCCU it also handles Fuel Control.
Example: When “dual
fuel” Start is initiated manually by the operator, the Plant
Control will start the
automatic start sequence which will initiate start-up of the sealing oil pump.
When the engine condition for Dual Fuel running, which is monitored by the
GECU, is confirmed
to meet the prescribed
demands, the Plant Control releases a “Start Dual Fuel Operation” signal for
the GCCU (Fuel Control).
In combination with the
GCCU, the GECU will effect the fuel gas injection if all conditions for Dual
Fuel running are fulfilled.
The Plant Control
monitors the condition of the following:
•
HC
“Sensors”
•
Gas
Supply System
•
Sealing
Oil System
•
Pipe
Ventilation
•
Inert
Gas System
•
Network
connection to other units of
the Dual Fuel System
and, if a failure
occur, the Plant Control will automatically interrupt fuel gas start operation and return the plant to Gas Safe
Condition.
The GECU also contains
the Fuel Control which includes all facilities required for calculating the
fuel gas index and the Pilot Oil index based on the command from the
conventional governor and the actual active mode.
Based on these data and
including information about the fuel gas pressure, the Fuel Control calculates
the start and duration time of the injection, then sends the signal to GCCU
which effectuates the injection by controlling the ELGI valve.
GACU, Auxiliary Control
The GACU contains
facilities necessary to control the following auxiliary systems: The fan for
ventilating of the double wall pipes, the sealing oil pump, the purging with
inert gas and the gas supply system.
The GACU controls:
•
Start/stop of pumps, fans, and of the gas supply system.
•
The sealing oil pressure set points
•
The pressure set points for the gas supply system.
GCCU, ELGI control
The GCCU controls the
ELGI valve on the basics of data calculated by the GECU.
In due time before each
injection the GCU receives information from the GECU of start timing for fuel
gas injection, and the time for the injection valve to stay open. If the GCCU
receive a signal ready from the safety system and GCCU observes no
abnormalities then the injection of fuel gas will starts at the relevant
crankshaft position.
The GSSU, fuel gas
System Monitoring and Control
The
GSSU performs safety monitoring of the fuel gas System and controls the fuel
gas Shut Down.
It monitors the
following:
•
Status of exhaust gas temperature
•
Pipe ventilation of the double wall piping
•
Sealing Oil pressure
•
Fuel gas Pressure
•
GCSU ready signal
If one of the above
parameters, referring to the relevant fuel gas state differs from normal
service value, the GSSU overrules any other signals and fuel gas shut down will
be released.
After the cause of the
shut down has been corrected the fuel gas operation can be manually restarted.
GCSU, PMI on-line
The purpose of the
GCSUs is to monitor the cylinders for being in condition for injection of fuel
gas. The following events are monitored:
•
Fuel gas accumulator pressure drop during injection
•
Pilot oil injection pressure
•
Cylinder pressure:
Low compression
pressure Knocking
Low Expansion pressure
•
Scavenge air pressure
If one of the events is
abnormal the ELGI valve is closed and a shut down of fuel gas is activated by
the GSSU.
Safety remarks
The
primary design target of the dual fuel concept is to ensure a Dual Fuel Control
System which will provide the highest possible degree of safety to personnel.
Consequently, a failure in the gas system will, in general, cause shut down of
fuel gas running and subsequent purging of pipes and accumulators
Fuel
gas operation is monitored by the safety system, which will shut down fuel gas
operation in case of failure. Additionally, fuel gas operation is monitored by
the Plant Control and the Fuel Control, and fuel gas operation is stopped if
one of the systems detects a failure. As parameters vital for fuel gas
operation are monitored, both by the Plant Control/ Fuel Control and the Safety
Control System, these systems will provide mutual back-up.
Conclusion
The
above chapters reveal the differences in principle and service experiences of
Latest Marine two stroke Engines in the Shipping Industry. Developments in the
Marine engines gives the advantages to the Owners as well as the Operators with
High Efficiency, Lower Fuel consumption, Better maneuverability, Ease of
Maintenance and Lower Emissions. Continuous Research and development is ongoing
to achieve, the future Marine Environmental Protection standards for Cleaner Oceans and Safer Ships.
Abbreviations
BIBLOGRAPHY
[1] P. Sunn Pedersen: “Development
Towards the Intelligent Engine”, 16th International Marine Propulsion
Conference, London 10-11 March 1994, Proceedings pp 77-88
[2] P. Sørensen & P. Sunn
Pedersen: “The Intelligent Engine and Electronic Products - A Development
Status”. Proceedings of the 22nd CIMAC International Congress on Combustion
Engines, Copenhagen 18-21 May 1998, pp 551-564
[3] ‘Utilisation of VOC in Shuttle
Tankers’, MAN B&W Diesel A/S, company publication P.342-98.11, 1998 (25
pages)
[4] P. Sunn Pedersen & P.
Sørensen: ‘Computer Controlled System for two-stroke Machinery (A Progress
Report)’. 22nd Marine Propulsion Conference, Amsterdam 29-30 March 2000.
Conference Proceedings, pp 17–33.
[5]
H.SAKABE and M.OKABE, The UEC-LSⅡ/LSE Engine Development Program, CIMAC
2001, pp. 28-37
[6]
S.LAULISTEN, J.DRAGSTED, and B.BUCHOLZ, Swirl
Injection Lubrication, CIMAC 2001, pp. 921-932
[7]
H.SAKABE and K.SAKAGUCHI, The UEC Engine Development Program and Its Latest
Development, CIMAC Kyoto 2004
[8]
K.SAKAGUCHI and M.SUGIHARA, The Development of the Electronically Controlled
Engine “MITSUBISHI UEC Eco-Engine,” CIMAC Kyoto 2004
[9]
“LNG Carriers with Low Speed Diesel Propulsion”, Ole Grøne, The SNAME Texas
Section14th Annual Offshore Symposium, November 10, 2004, Houston, Texas
[10]
“Basic Principles of Ship Propulsion”, p.254 – 01.04, January 2004, MAN B&W
Diesel A/S
[11]
“ME-GI Engines for LNG Application” System Control and Safety Feb. 2005 Ole
Grøne, Kjeld Aabo, Rene Sejer Laursen, MAN B&W Diesel A/S Steve
Broadbent,Flotech
[12] Wartzila NSD website
13] Man B & W
Website
15 comments:
respected sir your article is interesting but where are the diagrams and figures?????it is difficult to understand without all those.
I would also wish to get access on those diagrams being able to understand better... Great work anyway.
for diagrams refer-
http://oldcampus.aams.dk/file.php?file=%2F192%2FMAN_B_W_ME_Praesentation.pdf
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