Benefits of spark-ignition engine fuel-saving technologies under transient part load operations

Authors

  • W.S.I.W. Salim Faculty of Mechanical & Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia, 86400, Parit Raja, Johor, Malaysia
  • A.A.M. Mahdi Faculty of Mechanical & Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia, 86400, Parit Raja, Johor, Malaysia
  • M.I. Salim Imperial College London, South Kensington, London, SW7 2AZ
  • M.A. Abas Low Carbon Transport Research Centre, Universiti Teknologi Malaysia 81310 Johor Bahru, Johor, Malaysia
  • R.F. Martinez-Botas Imperial College London, South Kensington, London, SW7 2AZ
  • S. Rajoo Low Carbon Transport Research Centre, Universiti Teknologi Malaysia 81310 Johor Bahru, Johor, Malaysia

DOI:

https://doi.org/10.15282/jmes.11.4.2017.6.0272

Keywords:

Fuel economy; cylinder deactivation; stop-start system; engine downsizing; transient part-load operations.

Abstract

This paper presents a simulation-based study to evaluate three potential benefits of fuelsaving technologies implemented in spark-ignition (SI) engines for a passenger car over actual urban driving cycles. These technologies include cylinder deactivation (CDA), stop-start system, and engine downsizing (≈20% degree of downsizing). The aim of the work is to evaluate individual benefits of each system in terms of fuel consumption. GTPower engine simulation tool is utilised to model engines which employ each of the mentioned technologies; each of the engines has identical full-load torque characteristics. Each engine model is instructed to run over a transient, part-load, torque driven operations based on actual road test measurements, and the cycle-averaged fuel consumption was evaluated. From the analysis, the contribution of each technology in terms of fuel economy can be assessed based on an actual part-load transient operation, which can be beneficial to developers to optimise the operation of SI engines. The results revealed stopstart system to be the most promising technology for the driving cycle at hand with 27.5% fuel consumption improvement over the baseline engine. CDA engine allows for 12.6% fuel economy improvement. On the other hand, the downsized turbocharged engine has caused increasing cycle fuel consumption by 7.5%. These findings are expected to be valid for typical urban driving cycles as far as they conform to the operating load residency points over the transient torque profile.

References

Mellios G, Hausberger S, Keller M, Samaras L, Ntaziachristos L. Parameterisation of fuel consumption and CO2 emissions of passenger cars and light commercial vehicles for modelling purposes. Luxembourg: European Union; 2011.

Mock P, German J, Bandivadekar A, Riemersma I. Discrepancies between type approval and “real-world” fuel consumption and CO2 values: Assessment for 2001-2011 European passenger cars. The International Council of Clean Transportation; 2012.

Wahono B, Nur A, Santoso WB, Praptijanto A. A comparison study of range-extended engines for electric vehicle based on vehicle simulator. Journal of Mechanical Engineering and Sciences. 2016;10:1803-16.

Bates B, Dosdall JM, Smith DH. Variable Displacement by Engine Valve Control. SAE Technical Paper 7801451978.

Kuruppu C, Pesiridis A, Rajoo S. Investigation of cylinder deactivation and variable valve actuation on gasoline engine performance. SAE Technical Paper Series 2014-01-11702014.

Hu B, Copeland C, Lu P, Akehurst S, Brace C. A new de-throttling concept in a twin-charged gasoline engine system. SAE Int J Engines. 2015;8:1553 - 61.

Rebbert M, Kreusen G, Lauer S. A new cylinder deactivation by FEV and Mahle. SAE Technical Paper 2008-01-13542008.

Souflas I, Mason B, Cary M, Schaal P. Mode Transition optimisation process for variable displacement engines. SAE Technical Paper 2016-01-06192016.

Abas MA, Abidin SFZ, Rajoo S, Martinez-Botas R, Ismail MI. Evaluation between engine stop/start and cylinder deactivation technologies under southeast asia urban driving condition. SAE Technical Paper 2017-01-09862017.

Robinette D, Powell M. Optimizing 12 volt start - stop for conventional powertrains. SAE International Journal of Engines. 2011;4:837-49.

Wellmann T, Govindswamy K, Tomazic D. Integration of engine start/stop systems with emphasis on NVH and launch behavior. SAE International Journal of Engines. 2013;6:1368-78.

Wellmann T, Govindswamy K, Orzechowski J, Srinivasan S. Influence of automatic engine stop/start systems on vehicle NVH and launch performance. SAE International Journal of Engines. 2015;8:1938-46.

Koltsakis G, Samaras Z, Karvountzis-Kontakiotis A, Zacharopoulou T, Haralampous O. Implications of engine start-stop on after-treatment operation. SAE International Journal of Engines. 2011;4:1571-85.

Turner J, Popplewell A, Patel R, Johnson T, Darnton N, Richardson S, et al. Ultra boost for economy: extending the limits of extreme engine downsizing. SAE International Journal of Engines. 2014;7:387-417.

Bassett M, Hall J, Hibberd B, Borman S, Reader S, Gray K, et al. Heavily downsized gasoline demonstrator. SAE International Journal of Engines. 2016;9:729-38.

Salamon C, McAllister M, Robinson R, Richardson S, Martinez-Botas R, Romagnoli A, et al. Improving fuel economy by 35% through combined turbo and supercharging on a spark ignition engine. Proceedings of the 21st Aachen Colloquium Automobile and Engine Technology 2012, 8–10 October. Aachen; 2012.

Abas A, Salim O, Martinez-Botas R, Rajoo S. Efforts to establish malaysian urban drive-cycle for fuel economy analysis. SAE Technical Paper 2014-01-11592014.

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Published

2017-12-31

How to Cite

[1]
W. Salim, A. Mahdi, . M. Salim, M. Abas, R. Martinez-Botas, and S. Rajoo, “Benefits of spark-ignition engine fuel-saving technologies under transient part load operations”, J. Mech. Eng. Sci., vol. 11, no. 4, pp. 3027–3037, Dec. 2017.

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