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Erschienen in:
Horizons in Internal Combustion Research Kapitel lesen Erstes Kapitel lesen

2018 | OriginalPaper | Buchkapitel

Future Mobility Solutions of Indian Automotive Industry: BS-VI, Hybrid, and Electric Vehicles

verfasst von : Tadveer Singh Hora, Akhilendra Pratap Singh, Avinash Kumar Agarwal

Erschienen in: Advances in Internal Combustion Engine Research

Verlag: Springer Singapore

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Abstract

Worldwide scientists and researchers are concerned about climate change and global warming. Automotive vehicles are a major source for emission of greenhouse gases (GHG) and particulate matter (PM). Complying with strict BS-VI emission norms require improvised engine calibration, complex after-treatment (DOC, SCR, and DPF) system calibration, infrastructure development and engine validation. BS-VI will significantly reduce GHG and atmospheric PM, but with long-term perspective, an alternate solution is required to develop zero-emission vehicles. Recently, government planned to debar gasoline and diesel vehicles by 2030. In this scenario, Indian automotive industry has to be future-ready. The future disruptions in Indian automotive would include implementation of hybrid, electric, and fuel-cell vehicles. Government has started working in infrastructure development of hybrid and electric vehicles such as charging units, battery development, charging infrastructure development. However, currently hybrid and electric vehicles are significantly costlier and are required to be economically feasible. It can be assumed that conventional gasoline engines will be used in hybrid vehicles. Diesel engines would also be difficult to be phased out since implementation of hybrid/electric vehicles in long-haul vehicles and high-tonnage vehicles would remain challenging, where diesel engines are currently used virtually unchallenged by any other technology options.

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Vorheriges Kapitel Application of CFD for Analysis and Design of IC Engines
Literatur
1.
Onishi S, Jo SH, Shoda K, Jo PD, Kato S (1979) Active thermo-atmosphere combustion (ATAC)—a new combustion process for internal combustion engines. SAE Technical Paper; 790501
2.
Najt PM, Foster DE (1983) Compression-ignited homogeneous charge combustion. SAE Technical Paper; 830264
3.
Thring RH (1989) Homogeneous-charge compression ignition (HCCI) engines. SAE Technical Paper; 892068
4.
Stanglmaier RH, Roberts CE (1999) Homogeneous charge compression ignition (HCCI): benefits, compromise and future engine applications. SAE Technical Paper; 1999-01-3682
5.
Maurya RK, Agarwal AK (2011) Experimental investigation on the effect of intake air temperature and air-fuel ratio on cycle-to-cycle variations of HCCI combustion and performance parameters. Appl Energy 88(4):1153–1163CrossRef
6.
Gan S, Ng HK, Pang KM (2011) Homogeneous charge compression ignition (HCCI) combustion: implementation and effects on pollutants in direct injection diesel engines. Appl Energy 88:559–567
7.
Dec JE, Kelly-Zion PL (2000) The effects of injection timing and diluents addition on late-combustion soot burnout in a DI diesel engine based on simultaneous 2-D imaging of OH and soot. SAE Technical Paper; 2000-01-0238
8.
Ryan III TW, Callahan TJ (1996) Homogeneous charge compression ignition of diesel fuel. SAE Technical Paper; 961160
9.
Gray III AW, Ryan III TW (1997) Homogeneous charge compression ignition of diesel fuel. SAE Technical Paper; 971676
10.
Singh AP, Agarwal AK (2012) Combustion characteristics of diesel HCCI engine: an experimental investigation using external mixture formation technique. Appl Energy 99:116–125CrossRef
11.
Singh G, Singh AP, Agarwal AK (2014) Experimental investigations of combustion, performance and emission characterization of biodiesel fuelled HCCI engine using external mixture formation technique. Sustain Energy Technol Assess 6:116–128
12.
Simescu S, Ryan TW, Neely GD, Matheaus AC, Surampudi B (2002) Partial pre-mixed combustion with cooled and uncooled EGR in a heavy-duty diesel engine. SAE Technical Paper; 2002-01-0963
13.
Weiskirch C, Mueller E (2007) Advanced in diesel engine combustion: split combustion. SAE Technical Paper; 2007-01-0178
14.
Benajes J, Molina S, García A, Monsalve-Serrano J (2015) Effects of low reactivity fuel characteristics and blending ratio on low load RCCI (reactivity controlled compression ignition) performance and emissions in a heavy-duty diesel engine. Energy 90:1261–1271CrossRef
15.
Li J, Yang WM, Zhou DZ (2017) Review on the management of RCCI engines. Renew Sustain Energy Rev 69:65–79CrossRef
16.
Li J, Yang WM, An H, Zhou DZ, Yu WB, Wang JX et al (2015) Numerical investigation on the effect of reactivity gradient in an RCCI engine fueled with gasoline and diesel. Energy Convers Manag 92:342–352CrossRef
17.
Nieman DE, Dempsey AB, Reitz RD (2012) Heavy-duty RCCI operation using natural gas and diesel. SAE Int J Eng 5:270–285CrossRef
18.
Salahi MM, Esfahanian V, Gharehghani A, Mirsalim M (2017) Investigating the reactivity controlled compression ignition (RCCI) combustion strategy in a natural gas/diesel fueled engine with a pre-chamber. Energy Convers Manag 132:40–53CrossRef
19.
Dahodwala M, Joshi S, Koehler E, Franke M, Tomazic D (2015) Experimental and computational analysis of diesel-natural gas RCCI combustion in heavy-duty engines. SAE Technical Paper; 2015-01-0849
20.
Jia Z, Denbratt I (2015) Experimental investigation of natural gas-diesel dual-fuel RCCI in a heavy-duty engine. SAE Int J Eng 8:797–807CrossRef
21.
Pipitone E, Genchi G (2016) NO x reduction and efficiency improvements by means of the Double Fuel HCCI combustion of natural gas–gasoline mixtures. Appl Therm Eng 102:1001–1010CrossRef
22.
Dempsey AB, Walker NR, Reitz R (2013) Effect of cetane improvers on gasoline, ethanol, and methanol reactivity and the implications for RCCI combustion. SAE Int J Fuels Lubr 6:170–187CrossRef
23.
Li Y, Jia M, Liu Y, Xie M (2013) Numerical study on the combustion and emission characteristics of a methanol/diesel reactivity controlled compression ignition (RCCI) engine. Appl Energy 106:184–197CrossRef
24.
Li Y, Jia M, Chang Y, Liu Y, Xie M, Wang T et al (2014) Parametric study and optimization of a RCCI (reactivity controlled compression ignition) engine fueled with methanol and diesel. Energy 65:319–332CrossRef
25.
Splitter DA, Reitz RD (2014) Fuel reactivity effects on the efficiency and operational window of dual-fuel compression ignition engines. Fuel 118:163–175CrossRef
26.
Curran S, Hanson R, Wagner R (2012) Effect of E85 on RCCI performance and emissions on a multi-cylinder light-duty diesel engine. SAE Technical Paper; 2012-01-0376
27.
Zhang Y, Sagalovich I, Ojeda WD, Ickes A, Wallner T, Wickman DD (2013) Development of dual-fuel low temperature combustion strategy in a multi-cylinder heavy-duty compression ignition engine using conventional and alternative fuels. In: SAE technical paper, SAE international, pp 1481–1489
28.
Qian Y, Ouyang L, Wang X, Zhu L, Lu X (2015) Experimental studies on combustion and emissions of RCCI fueled with n-heptane/alcohols fuels. Fuel 162:239–250CrossRef
29.
Qian Y, Wang X, Zhu L, Lu X (2015) Experimental studies on combustion and emissions of RCCI (reactivity controlled compression ignition) with gasoline/ n-heptane and ethanol/n-heptane as fuels. Energy 88:584–594CrossRef
30.
DelVescovo D, Wang H, Wissink M, Reitz R (2015) Iso-butanol as both low reactivity and high reactivity fuels with addition of Di-Tert Butyl Peroxide (DTBP) in RCCI combustion. SAE Int J Fuels Lubr 8:329–343CrossRef
31.
Wang H, DelVescovo D, Yao M, Reitz RD (2015) Numerical study of RCCI and HCCI combustion processes using gasoline, diesel, iso-butanol and DTBP cetane improver. SAE Int J Eng 8(2):831–845CrossRef
32.
Liu H, Wang X, Zheng Z, Gu J, Wang H, Yao M (2014) Experimental and simulation investigation of the combustion characteristics and emissions using n-butanol/biodiesel dual-fuel injection on a diesel engine. Energy 74:741–752CrossRef
33.
Kokjohn SL, Hanson RM, Splitter DA, Reitz RD (2011) Fuel reactivity controlled compression ignition (RCCI): a pathway to controlled high-efficiency clean combustion. Int J Eng Res 12:209–226CrossRef
34.
Dempsey AB, Reitz RD (2011) Computational optimization of a heavy-duty compression ignition engine fueled with conventional gasoline. SAE Int J Eng 4:338–359CrossRef
35.
Jia M, Dempsey AB, Wang H, Li Y, Reitz RD (2015) Numerical simulation of cyclic variability in reactivity-controlled compression ignition combustion with a focus on the initial temperature at intake valve closing. Int J Eng Res 16:441–460CrossRef
36.
Molina S, García A, Pastor JM, Belarte E, Balloul I (2015) Operating range extension of RCCI combustion concept from low to full load in a heavy-duty engine. Appl Energy 143:211–227CrossRef
37.
Benajes J, Pastor JV, García A, Monsalve-Serrano J (2015) The potential of RCCI concept to meet EURO VI NOx limitation and ultra-low soot emissions in a heavy-duty engine over the whole engine map. Fuel 159:952–961
38.
39.
40.
41.
42.
43.
44.
45.
46.
47.
48.
49.
50.
51.
Suresh M, Hari Prakash, Durga Prasad B (2015) Operation and developments of DISI engines—a review. Int R J Latest Trends Eng Technol (IJLTET) 5(4):31–37
52.
53.
Internal data, Daimler Chrysler, General Motors, Ricardo
54.
Soylu S (ed) Electric vehicles-modelling and simulations. ISBN 978-953-307-477
55.
56.
Fuhs AE (2009) Hybrid vehicles and the future of personal transportation. CRC Press
57.
58.
59.
Agarwal AK, Shukla PC, Patel C, Gupta JG, Sharma N, Prasad RK, et al (2016) Unregulated emissions and health risk potential from biodiesel (KB5, KB20) and methanol blend (M5) fuelled transportation diesel engines. Renew Energy
60.
Metadaten
Titel
Future Mobility Solutions of Indian Automotive Industry: BS-VI, Hybrid, and Electric Vehicles
verfasst von
Tadveer Singh Hora
Akhilendra Pratap Singh
Avinash Kumar Agarwal
Copyright-Jahr
2018
Verlag
Springer Singapore
Buch
Advances in Internal Combustion Engine Research

Print ISBN: 978-981-10-7574-2

Electronic ISBN: 978-981-10-7575-9

Copyright-Jahr: 2018

DOI
https://doi.org/10.1007/978-981-10-7575-9_14

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