Development of a pre-ignition submodel for hydrogen engines

In hydrogen-fuelled spark ignition engine applications, the onset of pre-ignition remains one of the prime limitations that needs to be addressed to avoid its incidence and achieve superior performance. This paper describes a new pre-ignition submodel for engine modelling codes. The effects of changes in key operating variables, such as compression ratio, spark timing, intake pressure, and temperature on pre-ignition limiting equivalence ratios are established both analytically and experimentally. With the established pre-ignition model, it is possible not only to investigate whether pre-ignition is observed with changing operating and design parameters, but also to evaluate those parameters' effects on the maximum possible pre-ignition intensity.

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The Fuel Mix Limits and Efficiency of a Stoichiometric, Ammonia, and Gasoline Dual Fueled Spark Ignition Engine

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.2898837 ◽

2008 ◽

Vol 130 (4) ◽

Cited By ~ 45

Author(s):

Shawn M. Grannell ◽

Dennis N. Assanis ◽

Stanislav V. Bohac ◽

Donald E. Gillespie

Keyword(s):

Compression Ratio ◽

Maximum Load ◽

Spark Ignition ◽

Spark Ignition Engine ◽

Significant Fraction ◽

Gaseous Ammonia ◽

Spark Ignition Engines ◽

Stoichiometric Mixture ◽

Brake Torque ◽

Spark Timing

An overall stoichiometric mixture of air, gaseous ammonia, and gasoline was metered into a single cylinder, variable compression ratio, supercharged cooperative fuel research (CFR) engine at varying ratios of gasoline to ammonia. The engine was operated such that the combustion was knock-free with minimal roughness for all loads ranging from idle up to a maximum load in the supercharge regime. For a given load, speed, and compression ratio, there was a range of ratios of gasoline to ammonia for which knock-free, smooth firing was obtained. This range was investigated at its rough limit and also at its maximum brake torque (MBT) knock limit. If too much ammonia was used, then the engine fired with an excessive roughness. If too much gasoline was used, then knock-free combustion could not be obtained while the maximum brake torque spark timing was maintained. Stoichiometric operation on gasoline alone is also presented, for comparison. It was found that a significant fraction of the gasoline used in spark ignition engines could be replaced with ammonia. Operation on about 100% gasoline was required at idle. However, a fuel mix comprising 70% ammonia∕30% gasoline on an energy basis could be used at normally aspirated, wide open throttle. Even greater ammonia to gasoline ratios were permitted for supercharged operation. The use of ammonia with gasoline allowed knock-free operation with MBT spark timing at higher compression ratios and higher loads than could be obtained with the use of gasoline alone.

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EGR Effect On Performance of a Spark Ignition Engine Fueled with Blend of Methanol-Gasoline

Wasit Journal of Engineering Sciences ◽

10.31185/ejuow.vol1.iss2.19 ◽

2013 ◽

Vol 1 (2) ◽

pp. 110-92

Author(s):

Miqdam Tariq Chaichan

Keyword(s):

Fuel Consumption ◽

Compression Ratio ◽

Spark Ignition ◽

Spark Ignition Engine ◽

Specific Fuel Consumption ◽

Exhaust Gas ◽

Brake Specific Fuel Consumption ◽

Test Results ◽

Brake Thermal Efficiency ◽

Spark Timing

This paper examines the results of performance of a single cylinder spark- ignition engine fuelled with 20% methanol +80% gasoline (M20), compared to gasoline. The experiments were conducted at stoichiometric air–fuel ratio at wide open throttle and variable speed conditions, over the range of 1000 to 2600 rpm. The tests were conducted at higher useful compression ratio using optimum spark timings and adding recirculated exhaust gas with 20% to suction manifold. The test results show that the higher compression ratio for the tested gasoline was 7:1, 9.5:1 for M20 and 9:1 for M20 with added EGR. M20 at higher useful compression ratio (HUCR) and optimum spark timing (OST) characteristics are significantly different from gasoline. Within the tested speed range, M20 consistently produces higher brake thermal efficiency by about 6%. Also it resulted in approximately 3.06% lower brake specific fuel consumption compared with gasoline. Adding EGR to M20 caused reduction in HUCR and advancing the OST. This addition increased brake specific fuel consumption (BSFC), reduced brake thermal energy, volumetric efficiency and exhaust gas temperatures.

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Effects of hydrogen addition on engine performance in a spark ignition engine with a high compression ratio under lean burn conditions

International Journal of Hydrogen Energy ◽

10.1016/j.ijhydene.2019.04.120 ◽

2019 ◽

Vol 44 (29) ◽

pp. 15565-15574 ◽

Cited By ~ 12

Author(s):

Masaki Naruke ◽

Kohei Morie ◽

Satoshi Sakaida ◽

Kotaro Tanaka ◽

Mitsuru Konno

Keyword(s):

Compression Ratio ◽

Engine Performance ◽

Spark Ignition ◽

Spark Ignition Engine ◽

High Compression Ratio ◽

Lean Burn ◽

Hydrogen Addition ◽

High Compression

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Numerical comparative study on knocking combustion of high compression ratio spark ignition engine fueled with methanol, ethanol and methane based on detailed chemical kinetics

Fuel ◽

10.1016/j.fuel.2021.121615 ◽

2021 ◽

Vol 306 ◽

pp. 121615

Author(s):

Xiaoyan Li ◽

Xudong Zhen ◽

Shuaiqing Xu ◽

Yang Wang ◽

Daming Liu ◽

...

Keyword(s):

Comparative Study ◽

Chemical Kinetics ◽

Compression Ratio ◽

Spark Ignition ◽

Spark Ignition Engine ◽

High Compression Ratio ◽

Detailed Chemical Kinetics ◽

High Compression ◽

Detailed Chemical

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Simulation of Extended Expansion Lean Burn Spark Ignition Engine

ASME 2004 Internal Combustion Engine Division Fall Technical Conference ◽

10.1115/icef2004-0822 ◽

2004 ◽

Author(s):

A. Manivannan ◽

R. Ramprabhu ◽

P. Tamilporai ◽

S. Chandrasekaran

Keyword(s):

Heat Transfer ◽

Compression Ratio ◽

Thermal Efficiency ◽

Numerical Study ◽

Spark Ignition ◽

Spark Ignition Engine ◽

Valve Closure ◽

Intake Valve ◽

Lean Burn ◽

Atkinson Cycle

This paper deals with Numerical Study of 4-stoke, Single cylinder, Spark Ignition, Extended Expansion Lean Burn Engine. Engine processes are simulated using thermodynamic and global modeling techniques. In the simulation study following process are considered compression, combustion, and expansion. Sub-models are used to include effect due to gas exchange process, heat transfer and friction. Wiebe heat release formula was used to predict the cylinder pressure, which was used to find out the indicated work done. The heat transfer from the cylinder, friction and pumping losses also were taken into account to predict the brake mean effective pressure, brake thermal efficiency and brake specific fuel consumption. Extended Expansion Engine operates on Otto-Atkinson cycle. Late Intake Valve Closure (LIVC) technique is used to control the load. The Atkinson cycle has lager expansion ratio than compression ratio. This is achieved by increasing the geometric compression ratio and employing LIVC. Simulation result shows that there is an increase in thermal efficiency up to a certain limit of intake valve closure timing. Optimum performance is attained at 90 deg intake valve closure (IVC) timing further delaying the intake valve closure reduces the engine performance.

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