Initial theoretical study for a heavy duty diesel engine conversion to biogas fuelling.
Irimescu, Adrian ; Ionel, Ioana ; Dungan, Luisa Isabela 等
1. INTRODUCTION
As it is the product of ideal combustion for any hydrocarbon fuel,
reducing carbon dioxide (C[O.sub.2]) emissions can only be achieved by
increasing efficiency or by using low carbon fuels. One way of combining
these two methods is using biogas in a cogeneration installation. While
new technologies like fuel cells are highly efficient, internal
combustion engines are very reliable, easily serviceable, can be quickly
started and shut down and adapt very well to partial loads (Irimescu et
al., 2009). As it features low cetane numbers, biogas is generally used
in spark ignition (SI) engines (Hunt, 2007). However, given the higher
fuel conversion efficiency of compression ignition (CI) engines, using
heavy duty diesel engines fuelled with biogas can significantly improve
fuel economy compared to employing SI engines.
When investigating such a conversion of diesel engines to biogas
operation, the use of a thermodynamic model such as the one presented in
this paper can reveal important aspects that can significantly
contribute to the successful operation of a cogeneration plant fuelled
with biogas. Control strategies can be based on the results obtained
from such theoretical studies and system optimization can be achieved in
order to gain maximum thermal efficiency with low emissions.
2. DUAL FUEL SYSTEMS AND EMISSIONS MITIGATION
Given that biogas has a low cetane number, a dual fuel system is
necessary when converting a diesel engine to biogas operation
(Papagiannakis et. al, 2010). Gaseous fuel is mixed with air prior to
the intake process, while diesel fuel is injected at the end of the
compression stroke to ignite the air-biogas mixture (Bedoya et. al,
2009). This liquid fuel injection is much shorter than under normal
diesel operation and is known as a "pilot injection".
CI engines, as well as biogas fuelled engines, operate on lean
mixtures. As a result, carbon monoxide (CO) and unburned hydrocarbons
emissions (HC) are relatively low (Papagiannakis et. al, 2010), and even
the strictest regulations can be complied with by using an oxidation
catalyst to treat the exhaust gases. The major issue is nitrous oxides
(N[O.sub.x]) emissions mitigation, as simple installations such like
three way catalytic converters are not efficient during lean operation.
For this reason, selective catalytic reduction (SCR) systems are used,
with very high efficiency, but also much more expensive (Saravanan &
Nagarajan, 2009).
[FIGURE 1 OMITTED]
3. THERMODYNAMIC MODEL
A simple model was used for calculating the main thermodynamic
parameters of the working cycle. Intake and exhaust were considered as
constant pressure processes, while for compression as well as expansion,
a constant polytropic coefficient was used. During combustion, heat
released through fuel oxidation ([Q.sub.f]) is transferred to the piston
as work (W), gases inside the cylinder are heated to a higher level of
internal energy (U) and part of [Q.sub.f] is lost to the walls of the
combustion chamber ([Q.sub.w]).
D[Q.sub.f] = dU + dW + d[Q.sub.w] (1)
where released heat [Q.sub.f], internal energy U, work W and heat
transferred to the walls [Q.sub.w] are all measured in J.
From ignition to completion, combustion was divided into three
separate processes. The first phase was considered as a constant
pressure increase (dp) rapid combustion, the second an isobaric process
at maximum pressure ([p.sub.max]), and finally a slow burn phase,
considered as an isothermal process, at maximum temperature
([T.sub.max]).
[p.sub.max] = [p.sub.i] + dp * [theta] (2)
where maximum pressure during combustion [p.sub.max] and the
pressure level at ignition pi are measured in Pa, rate of pressure
increase dp in Pa / deg and combustion duration 0 in deg.
As stationary engines are operated at constant speed, load was the
main factor that was analyzed. Fuel conversion efficiency for CI engines
is higher than that of SI engines.
Higher ratios are possible for SI engines when using biogas,
however, during partial load operation CI engines have the advantage of
lower pumping losses, resulting in a much better efficiency for light
loads.
4. OPERATIONAL STRATEGIES
Biogas lower heating value (LHV) depends on its composition. As a
result of biological material fermentation, methane and C[O.sub.2] are
produced, along with traces amounts of other elements. The quality of
biogas is given by its methane content, ranging from 50 % to 70 % and
higher, depending on operating parameters and organic material
(El-Mashad & Zhang, 2010).
A heavy duty diesel engine was used for analyzing the case study of
biogas fuelling. Main characteristics of this engine previously used in
railway propulsion systems are presented in table 1.
The use of biogas is limited to light loads of 39 % to 44 % by the
lower flammability limit, while for higher loads only up to 85 % of the
liquid fuel can be replaced by gas, as combustion becomes unstable above
this limit. Figure 2 shows the control strategy with calculated biogas
flow and figure 3 presents pilot injection quantity for the entire load
range of the engine considered for this case study, for different
methane concentration (50%, 60%, 70% and 80% C[H.sub.4]).
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
In addition to modifications required to be adopted in fuel control
strategy, a speed regulator must be used to keep engine speed at a
constant value so that power is delivered at the prescribed frequency.
Also, this regulator will control the quantity of fuel for the pilot
injection. Given that maximum power and fuel conversion efficiency is
obtained at an engine speed of 750 rev/min, an additional gearbox will
be required, so that the electrical generator speed is maintained at a
constant value of 3000 rev/min for power delivered at 50 Hz frequency.
5. CONCLUSIONS
A simple thermodynamic model was developed an used to evaluate
aspects of converting a heavy duty diesel engine to biogas fuelling in a
cogeneration installation. As it is obtained from biomass, biogas is
carbon neutral and by using it as a fuel in such an adapted CI engine, a
reduction of up to 85 % in C[O.sub.2] emissions can be achieved, while
obtaining a high overall thermal efficiency.
Future studies will include an experimental validation of the
control strategies developed based on the model presented in this work,
as well as investigations on adding a steam generator to cover high heat
loads during times when electrical load is low. Also, emissions
mitigation is another area of research that needs to be addressed when
converting such CI engines to dual fuel operation for using biogas in
cogeneration of heat and power installations.
6. ACKNOWLEDGEMENTS
Part of the work presented in this paper was supported by human
resources development grant POSDRU 89/1.5/S/57649, "Performanta
prin postdoctorat pentru integrarea pentru integrarea in aria europeana
de cercetare" PERFORM-ERA ID 57649, of the Ministry of Labour,
Family and Social Protection, Romania, co-financed by the European
Social Fund--Investing in People.
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Tab. 1. Engine characteristics
Maximum power 920 kW @ 750 rev/min
Specific fuel consumption 231 g/kWh @ 920 kW
Compression ratio 11,25
Displacement 133 litres
Bore x Stroke 280 mm x 360 mm
Number of cylinders 6
Boost pressure 0,86 mbar @ 920 kW
