Compression Ratio Effects on Performance, Efficiency, Emissions and Combustion in a Carbureted and PFI Small Engine

Attard, William P.; Konidaris, Steven; Hamori, Ferenc; Toulson, Elisa; Watson, Harry C.

doi:10.4271/2007-01-3623

Cited by 14 publications

(20 citation statements)

References 31 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However higher CRs make gasoline engines subject to engine knocking if lower octane number is used, also known as detonation [17]. Attard et al [18] researched the effect of CR on the engine performance, emissions and combustion parameters. The tests were carried out on a double-cylinder, fourstroke, 430 cc, naturally aspirated, gasoline engine.…”

Section: Introductionmentioning

confidence: 99%

Effect of compression ratio on the emission, performance and combustion characteristics of a gasoline engine fueled with iso-butanol/gasoline blends

Sayın

Balki

2015

Energy

View full text Add to dashboard Cite

Section: Introductionmentioning

confidence: 99%

Effect of compression ratio on the emission, performance and combustion characteristics of a gasoline engine fueled with iso-butanol/gasoline blends

Sayın

Balki

2015

Energy

View full text Add to dashboard Cite

“…Across all modes, it was evident that the test engine (~70 mm bore) could operate with considerably higher CR for a given MAP when compared to larger bore (80-100 mm), lower speed engines. This was demonstrated with normally aspirated results showing potential for engine operation at a compression ratio exceeding 13 [9].…”

Section: Experimental Enginementioning

confidence: 60%

“…The faster initial burn is caused by the higher mixture density, which improves the flame initiation and hence kernel growth. Furthermore, as the engine speed increases, the 0-10% MFB data shows identical trends when compared to the normally aspirated data [7,9,36] with increased CA durations over reduced time intervals. It is interesting to note that the increased retained residuals in the non-knock compensated regions above 6,000 rev/min, due to the higher backpressure previously described, slows the initial burn duration at high speeds as seen in the middle diagram of Figure 7.…”

Section: Combustion Analysismentioning

confidence: 67%

“…Figure 1 highlights a design image together with a sectional view of the engine design. To put the research into context, experimental engine results at the maximum specific output setting and associated CR of 10 are displayed in Figure 2, with further detail on the test engine previously published [7][8][9][10][11][12][13]. To reliably achieve 25 BMEP, the asymmetric (odd) fire configuration required the uneven flow conditions in the intake and exhaust systems to be accommodated in the engine design [12,13].…”

Section: Experimental Enginementioning

confidence: 99%

“…To reliably achieve 25 BMEP, the asymmetric (odd) fire configuration required the uneven flow conditions in the intake and exhaust systems to be accommodated in the engine design [12,13]. In addition to the turbocharged results displayed in Figure 2, the test engine achieved a maximum of 37% brake thermal efficiency in normally aspirated configuration [7,9]. However, this was only possible after CR optimization to compensate for the higher levels of dissociation, friction and heat losses associated with the smaller cylinder capacity.…”

Section: Experimental Enginementioning

confidence: 99%

See 2 more Smart Citations

Combustion System Development and Analysis of a Downsized Highly Turbocharged PFI Small Engine

Attard¹,

Toulson²,

Hamori³

et al. 2010

SAE Int. J. Engines

Self Cite

View full text Add to dashboard Cite

This paper provides some insight into the future direction for developing smaller capacity downsized engines, which will be needed to meet tight CO 2 targets and the world's future powertrain requirements. This paper focuses on the combustion system development and combustion analysis results for a downsized 0.43 liter highly turbocharged engine. The inline two cylinder engine used in experiments was specifically designed and constructed to enable 25 bar BMEP. Producing this specific output is one way forward for future passenger vehicle powertrains, enabling in excess of 50% swept capacity reduction whilst maintaining comparable vehicle performance. Previous experiments and analysis have found that the extent to which larger engines can be downsized while still maintaining equal performance is combustion limited. Hence, small engine combustion is explored over a number of parametric studies, including a range of manifold absolute pressures up to 270 kPa, engine speeds exceeding 10,000 rev/min and compression ratios ranging from 9 to 13. Experimental results indicate that small engine combustion hurdles can be overcome to reliably extend the specific output to 25 bar BMEP. This is believed to be the highest recorded specific output for a non-intercooled small spark ignition PFI engine operating on pump gasoline. However, the boosted combustion effects illustrate that the thermal efficiency is highly dependent on the combustion efficiency, which deteriorates rapidly if uncontrolled combustion, specifically knock in the endgas region is encountered. However, with this combustion system design strategy, potential drive cycle fuel consumption improvements in excess of 20% are still achievable.

show abstract

Evaluation of the passive pre-chamber ignition concept for future high compression ratio turbocharged spark-ignition engines

et al. 2019

View full text Add to dashboard Cite

The pre-chamber ignition concept is an attractive strategy to enable the operation of spark-ignition engines in lean or diluted conditions keeping a suitable combustion process. According to the results the benefits in lean conditions include the fastening of the combustion process, the improvement of combustion stability, the increase of combustion efficiency by lowering carbon monoxide and hydrocarbons emissions. Thus, the pre-chamber ignition concept, especially in its passive version, arises as a promising alternative for future spark-ignition engines for passenger car applications. In this framework, an experimental investigation has been carried out to evaluate the potential of passive pre-chamber ignition concept in a high compression ratio, turbocharged, port fueled spark-ignition engine, using 95 Research Octane Number gasoline. As a first step, a 1D Wave Action Model was generated to design the pre-chamber geometry taking the fuel available at the start of pre-chamber combustion and the pressure difference between the main chamber and pre-chamber as key parameters. In a second step, these pre-chamber designs were experimentally validated at high load/speed conditions (4500 rpm, 12.5 bar Indicated Mean Effective Pressure) and compared with the conventional spark-ignition concept. Experimental results show how the passive pre-chamber concept increases efficiency with good combustion stability and high combustion efficiency in stoichiometric conditions. Nevertheless, maximum lambda attainable with the passive system is similar than that of the conventional spark and much lower compared to the maximum levels reported for the active system.

show abstract

Compression Ratio Effects on Performance, Efficiency, Emissions and Combustion in a Carbureted and PFI Small Engine

Cited by 14 publications

References 31 publications

Effect of compression ratio on the emission, performance and combustion characteristics of a gasoline engine fueled with iso-butanol/gasoline blends

Effect of compression ratio on the emission, performance and combustion characteristics of a gasoline engine fueled with iso-butanol/gasoline blends

Combustion System Development and Analysis of a Downsized Highly Turbocharged PFI Small Engine

Evaluation of the passive pre-chamber ignition concept for future high compression ratio turbocharged spark-ignition engines

Contact Info

Product

Resources

About