Optimization of the Climate Control System for Pure Electric Vehicle
Abstract
Emission standards have become increasingly stringent, which has generated more interest in problems related to environmental pollution. However, the EV driving range suffers from A/C (air conditioning) for the comfort of the occupants, especially in very hot or cold climates. Therefore, the dimensioning of the A/C system is more important than the case of the conventional vehicle with internal combustion engine. Specifically, EV consumes electric power from the battery pack to control the comfort of the passenger compartment due not only to the absence of rejection of engine heat for internal heating, but to the lack of operating power of the engine compressor for cooling inside. Subsequently, the energy utilization for the cooling/warming of the lodge should be enhanced for the energy effectiveness of EV. In this document, we focus on the size of the cooling system because the temperature of the indoor air in hot climates is more sensitive to the thermal comfort of the passenger.
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Gadhave Subhash L, Ragit Satishchandra S. Process Optimization of Tung Oil Methyl Ester (Verniciafordii) using the Taguchi Approach, and Its Fuel Characterization. Biofuels. 2020; 11(1): 49–55p.
Rao Ravella Sreenivas, Ganesh, Kumar C, Shetty Prakasham R, et al. The Taguchi Methodology as a Statistical Tool for Biotechnology Application: A Critical Appraisal. Biotechnology. 2008; 3(4): 510–523p.
Mohammad Abdullah Al Faruque, Korosh Vatanparvar. Modeling, Analysis, and Optimization of Electric Vehicle HVAC System. IEEE Conferences. 2016; 25–28p.
Hendricks Terry J. Multi Variable Optimization of Electrically Driven Vehicle Air Conditioning System Using Transient Performance Analysis. National Renewable Energy Laboratory; 2003.
Jung-Ho Huh, Brandemuel Michael J. Optimization of Air-Conditioning System Operating Strategies for Hot and Humid Climates. Energy Build. 2008; 40(7): 1202–1213p.
Bongha Song, Jiwon Kwon, Yongsuk Kim. Air Conditioning System Sizing for Pure Electric Vehicle. World Electr Veh J. 2015; 7(3): 3–6p.
Napoleon Enteria, Hazim Awbi, Hiroshi Yoshino, editors. Desiccant Heating, Ventilating, and Air-Conditioning Systems. Singapore: Springer; 2017.
Quansheng Zhang, Shengbo Eben Li, Kun Deng (auth). Automotive Air Conditioning: Optimization, Control and Diagnosis. Springer, International Publishing; 2016.
Kaustubh Shete. Influence of Automotive Air Conditioning Load on Fuel Economy of IC Engine Vehicles. International Journal of Scientific & Engineering Research (IJSER). 2015; 6(8): 1–7p.
Alison Subiantoro, Kim Tiowoi, Ulrich Stimming. Energy Saving Measures for Automotive Air Conditioning (AAC) System. International Refrigeration and Air Conditioning Conference. 2014; Paper 1361.
Samruddhi Rao, Pragati Samant, Athira Kadampatta, Reshma Shenoy. An Overview of Taguchi Method: Evolution, Concept and Applications. International Journal of Scientific & Engineering Research (IJSER). 2013; 4(10): 1–4p.
Dingel Oliver, Junior Christine. Energy and Thermal Management, Air-Conditioning, and Waste Heat Utilization. 2nd ETA Conference, Berlin, Germany. Nov 22–23, 2018.
DOI: https://doi.org/10.37591/jotssn.v7i3.5416
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