Climate systems of urban electric buses

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This article considers the climate systems of urban electric buses from different manufacturers, as well as presents and compares their characteristics and diagrams. Climate systems with two vapor compression refrigeration machines, a dependent evaporator of the driver’s cabin, and a chiller-fan coil circuit are analyzed, the existing domestic microclimate system for an electric bus is considered, and the advantages and disadvantages of these systems are presented. The influence of the features of electric buses, such as the limited battery capacity and absence of an internal combustion engine as a heat source, on the concept and design features of their microclimate systems is shown. The features of climate systems for electric buses intended for operation in the territory of the Russian Federation are considered, including the following technical requirements of organizations operating city electric buses: dual-zone climate control, i.e., separately for the passenger salon and driver’s cabin, and the possibility of using an auxiliary heater operating by burning diesel fuel only at ambient temperatures below 0 ℃ and at relatively low ambient temperatures during the cold season. The review conducted in this article aims to identify ways to further improve the climate systems of urban electric buses and demonstrate the various criteria when comparing them and assessing their efficiency.

作者简介

Nikolai Lavrov

Bauman Moscow State Technical University

Email: 79035596471@yandex.ru
ORCID iD: 0000-0003-2324-8247
SPIN 代码: 9187-7444

Dr. Sci. (Tech.), Professor

俄罗斯联邦, Moscow

Mikhail Savinov

Bauman Moscow State Technical University; LATRAC

编辑信件的主要联系方式.
Email: sova89@mail.ru
ORCID iD: 0009-0000-2495-7323
SPIN 代码: 8268-0560

Senior Lecturer

俄罗斯联邦, Moscow; Moscow

参考

  1. GOST 30593-2015. Motor vehicles. Heating, ventilation and conditioning systems. Requirements for efficiency and safety. Moscow: Standartinform; 2016. (In Russ).
  2. GOST R 53828-2010. Vehicles. System of microclimate. Technical requirements and test methods. Moscow: Standartinform, 2010. (In Russ).
  3. GOST R 52021-2003. Power-driven vehicles and trailers. Classification and definitions. Moscow: Gosstandart Rossii, 2003. (In Russ).
  4. Boes J, Janssen E, Kauba M, et al. Active vibration reduction applied to the compressor of an air-conditioning unit for trams. In: Proceedings of the conference «Acoustics»; 2008 Jun 29-Jul 04; Darmstadt, Germany. Paris; 2008.
  5. Evarestov VM, Maksimov VA, Pozhivilov NV, et al. Overview of the introduction of electric buses KAMAZ-6282-12 and LiAZ-6274 in the bus depots of the city of Moscow. In: Problems of technical operation and car service of the rolling stock of road transport: Collection of scientific papers of the EATiS department, dedicated to the 90th anniversary of MADI, based on materials from 78 scientific-methodical and scientific- research conference MADI. 2020 Jan 28–29. Moscow; 2020:32–37. (In Russ).
  6. Specification for a large-capacity city electric bus with a low floor level. Official website of the Mayor of Moscow [internet] Accessed: 25.06.2023. Available from: https://www.mos.ru/dt/documents/obraztcy-dokumentov/view/184154220/
  7. Electric bus air conditioner. SONGZ [internet] Accessed: 25.06.2023. Available from: https://www.songzac.com/electric-bus-air-conditioner/
  8. Athenia MkII Series Electric Series. Thermo King [internet] Accesed: 25.06.2023. Available from: https://europe.thermoking.com/ru/bus-hvac/athenia-mkii-electric-series
  9. Product datasheets. Eberspaecher [internet] Accessed: 25.06.2023. Available from: https://www.eberspaecher.com/en/download-center/product-datasheets
  10. HVAC systems and components, the whole nine yards. Aurora [internet] Accessed: 25.06.2023. Available from: https://www.aurora-eos.com/en/products
  11. Tsvetkov O.B., Laptev Y.A., Mitropov V.V., et al. Kigaliyskaya popravka v kontekste global’nykh klimaticheskikh imperativov. Refrigeration Technology. 2019;108(4):24–30. doi: 10.17816/RF104211
  12. Electric bus and hybrid bus. Konvekta [internet] Accessed: 25.06.2023. Available from: https://www.konvekta.de/en/products/bus-air-conditioning/electric-hybrid-bus.html
  13. Patent RUS № 193446 / 29.10.2019. Byul. № 31. Zakatov AS., Starkova MG, Bratyakin ZL, et al. Climate system of urban electric buse. (In Russ) Accessed: 25.06.2023. Available from: https://patents.s3.yandex.net/RU193446U1_20191029.pdf

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2. Fig. 1. Scheme of the Songz climate system 1 — Rooftop of the salon; 2 — Rooftop of the cabin; 3 — Front box with evaporator; 4 — Diesel or electric liquid heater; 5 — Dependent interior heaters; 6 — Coolant pipelines; 7 — Refrigerant pipelines.

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3. Fig. 2. Scheme of the Thermo King and Eberspaecher climate system 1 — Rooftop of the salon; 2 — Front box with evaporator; 3 — Diesel or electric liquid heater; 4 — Dependent interior heaters; 5 — Coolant pipelines; 6 — Refrigerant pipelines.

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4. Fig. 3. Scheme of the Heavac climate system 1 — Rooftop; 2 — Roof fancoil units; 3 — Rear cabin heater; 4 — Front box; 5 — Diesel or electric liquid heater; 6 — Dependent interior heaters; 7 — Coolant pipelines.

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