2019, Volume 21, Issue 3
Strategic Study of CAE >> 2019, Volume 21, Issue 3 doi: 10.15302/J-SSCAE-2019.03.005
Strategic Research on Promoting Coordinated Development of Refining and Automobile Industries
China Sinopec Group, Beijing 100127, China
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Abstract
The rapid development of new energy vehicles such as electric vehicles and fuel cell vehicles has initiate the age of automobile power revolution. The internal combustion engine vehicle (ICEV) manufacturing industry and the petroleum production industry actively respond to the automobile power revolution by satisfying the latest requirement for emissions, upgrading the quality of oil products, and advancing the development of internal combustion engine technology. Although new energy vehicles have some advantages, they can not comprehensively replace the ICEVs in a short term. Gasoline electric hybrid vehicles with highefficiency internal combustion engines will significantly reduce pollutant and carbon emissions, which are in line with China’s national conditions. By 2050, ICEVs, gasoline electric hybrid vehicles, fuel cell vehicles, and pure electric vehicles will coexist based on their respective technological advantages. However, the ICEVs will still predominate in the automobile market by then, and the ependence of automobile power on liquid fuels will exceed 60%. Therefore, the petroleum refining and automobile manufacturing industries should develop coordinately by studying the combustion mechanism from a molecular perspective in the internal combustion engines; exploring the relationship between fuel composition, distillation range, and particulate matter emissions, and developing simplified models; developing and promoting high-quality fuels and high-grade lubricants to adapt to the low-carbon and emission reduction requirements in the era of automotive power diversification.
Keywords
automobile power revolution ; internal combustion engine technology ; oil quality ; coordinated development
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References
[ 1 ] International Energy Agency. Global EV outlook 2018 [R]. Paris: International Energy Agency, 2018.
[ 2 ] Information Trends LLC. Hydrogen fuel cell vehicles—A global analysis [R]. Washington D.C.: Information Trends LLC, 2018.
[ 3 ] Editorial Department of China Journal of Highway and Transport. Review on China’s automotive engineering research progress: 2017 [J]. China Journal of Highway and Transport, 2017, 30(6): 1–197. Chinese. link1
[ 4 ] Su W H, Zhang Z J, Liu R L, et al. Development trend for technology of vehicle internal combustion engine [J]. Strategic Study of CAE, 2018, 20(1): 97–103. Chinese. link1
[ 5 ] Zhao F Q. Rational assessment of the challenges, potentials and opportunities of internal combustion engines [N]. China Automotive News, 2019-03-07(004). Chinese.
[ 6 ] Krishna V S, Hari O B, Dheerendra S. A comprehensive review on hybrid electric vehicles: Architectures and components [J]. Journal of Modern Transportation, 2019, doi.org/10.1007/s40534-019-0184-3. link1
[ 7 ] Hu X G. Advances in battery technologies for electric vehicles [M]. Beijing: Chemical Industry Press, 2018. Chinese.
[ 8 ] Timmers V R J H, Achten P A J. Non-exhaust PM emissions from electric vehicles [J]. Atmospheric Environment, 2016, 134: 10–17. link1
[ 9 ] Zhang X X, Wang Y Y, Liu Y, et al. Recent progress in disposal and recycling of spent lithium-ion batteries [J]. Chemical Industry and Engineering Progress, 2016, 35(12): 4026–4032. Chinese. link1
[10] Zheng X H, Zhu Z W, Lin X, et al. A mini-review on metal recycling from spent lithium ion batteries [J]. Engineering, 2018 (4): 361–370. link1
[11] Kalghatgi G T. The outlook for transport fuels: Part 1 [J]. Petroleum Technology Quarterly, 2016 (Q1): 23–31.
[12] Kalghatgi G T, Gosling C, Wier M J. The outlook for transport fuels: Part 2 [J]. Petroleum Technology Quarterly, 2016 (Q2): 17–23.
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