Impact of Large-Scale Electric Vehicles’ Promotion in Thailand Considering Energy Mix, Peak Load, and Greenhouse Gas Emissions

IF 7 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC Smart Cities Pub Date : 2023-10-02 DOI:10.3390/smartcities6050118
Ashok Paudel, Watcharakorn Pinthurat, Boonruang Marungsri
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Abstract

Thailand’s policies are in accord with the global drive to electrify transportation vehicle fleets due to climate concerns. This dedication is evident through its adoption of the 30@30 initiative and the planned ban on new internal combustion (IC) engine vehicles by 2035, showcasing a strong commitment. The objective of this study was to utilize the Low Emission Analysis Platform (LEAP) software to model the transition possibilities for electric vehicle (EV). Emphasis was placed on the future of the light-duty vehicle (LDV) sector, encompassing the energy sources, electric power demands, and greenhouse gas (GHG) emissions. Two scenarios were evaluated: one involving rapid economic growth and the other characterized by a more-gradual expansion. The former projection foresees 382 vehicles per thousand people by 2040, while the latter estimate envisions 338 vehicles. In the scenario of high growth, the vehicle stock could surge by 70% (27-million), whereas in the case of low growth, it might experience a 47% rise (23.3-million) compared to the base year (15.8 million). The increased adoption of EVs will lead to a decrease in energy demand owing to improved fuel efficiency. Nonetheless, even in the most-extreme EV scenarios, the proportion of electricity in the energy mix will remain below one-third. While GHG emissions will decrease, there is potential for even greater emission control through the enforcement of stricter emission standards. Significant EV adoption could potentially stress power grids, and the demand for charging might give rise to related challenges. The deployment of public fast charging infrastructure could provide a solution by evenly distributing the load across the day. In the most-rapid EV penetration scenario, a public charging program could cap the demand at 9300 MW, contrasting with the 21,000 MW demand for home charging. Therefore, a recommended approach involves devising an optimal strategy that considers EV adoption, a tariff structure with incentives, and the preparedness of the infrastructure.
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考虑能源结构、峰值负荷和温室气体排放的泰国推广大型电动汽车的影响
泰国的政策与全球出于对气候问题的担忧而推动运输车辆电动化的努力是一致的。通过采用30@30倡议和计划到2035年禁止新型内燃机(IC)发动机汽车,可以明显看出这种奉献精神,展示了坚定的承诺。本研究的目的是利用低排放分析平台(LEAP)软件对电动汽车(EV)的过渡可能性进行建模。重点放在轻型汽车(LDV)行业的未来,包括能源、电力需求和温室气体(GHG)排放。对两种情况进行了评估:一种是经济快速增长,另一种是经济缓慢增长。前者预计到2040年每千人拥有382辆汽车,而后者预计每千人拥有338辆汽车。在高增长的情况下,汽车库存可能会激增70%(2700万辆),而在低增长的情况下,与基准年(1580万辆)相比,可能会增长47%(2330万辆)。由于燃油效率的提高,电动汽车的普及将导致能源需求的减少。尽管如此,即使在最极端的情况下,电力在能源结构中的比例也将保持在三分之一以下。虽然温室气体排放将减少,但通过执行更严格的排放标准,有可能实现更大的排放控制。电动汽车的大量采用可能会给电网带来压力,对充电的需求可能会带来相关挑战。部署公共快速充电基础设施可以通过在一天中均匀分配负载来提供解决方案。在电动汽车普及速度最快的情况下,公共充电计划可以将需求限制在9300兆瓦,而家庭充电需求为2.1万兆瓦。因此,建议的方法包括设计一个考虑电动汽车采用、具有激励措施的关税结构和基础设施准备的最佳策略。
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来源期刊
Smart Cities
Smart Cities Multiple-
CiteScore
11.20
自引率
6.20%
发文量
0
审稿时长
11 weeks
期刊介绍: Smart Cities (ISSN 2624-6511) provides an advanced forum for the dissemination of information on the science and technology of smart cities, publishing reviews, regular research papers (articles) and communications in all areas of research concerning smart cities. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible, with no restriction on the maximum length of the papers published so that all experimental results can be reproduced.
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