基于气体旁通蒸发技术的制热量提升研究

doi:10.19784/j.cnki.issn1672-0172.2022.99.042

摘要/Abstract

摘要： 随着国家对节能减排要求的提高,房间空调器作为家用电器中的耗电大户,节能增效一直是各空调厂家研究的重中之重,也是用户的核心需求。气体旁通技术可以有效解决低温制热工况下,提升制热量同时减少压降,提高系统能效的问题。通过采用气体旁通强化换热技术,研究了采用气体旁通蒸发技术的冷凝器对房间空调器全年季节能效和制热量的影响,为相关技术领域提供参考。实验结果表明气体旁通系统的开关对提升系统制热量有促进作用,额定制热量提升3.8%,低温制热量提升5.9%,低温制热能效提升4.2%。对空调器全年能效消耗率提升3.3%。同时在系统调试时,需要考虑气体旁通系统补气量对能力的影响。

关键词: 气体旁通蒸发技术, 节能, 季节能效, 低温制热能力

Abstract: With the improvement of national requirements for energy conservation and emission reduction, room air conditioner as a large consumer of household appliances, its energy conservation and efficiency has always been the top priority of the research of air conditioning manufacturers, but also the core demand of users. Vapor-bypassed technology can effectively solve the problem of increasing heat production while reducing pressure drop and improving system energy efficiency especially under low temperature heating conditions. The effects of vapor-bypassed evaporation technology on annual seasonal energy efficiency and the heating capacity of room air conditioners were studied by using gas bypass enhanced heat transfer technology, so as to provide reference for related technical fields. The experimental results show that the switch of the gas bypass system can promote the heat production of the system, the rated heat production is increased by 3.8%, the low temperature heat production is increased by 5.9%, and the energy efficiency of low temperature heating is increased by 4.2%. The annual energy efficiency consumption rate of air conditioners increased by 3.3%. At the same time, it is necessary to consider the effect of volume flow rate of bypass gas on capacity during system commissioning.

Key words: Vapor-bypassed evaporation technology, Energy conservation, APF index, Low temperature heat capacity

中图分类号:

TB657.2

邵艳坡, 黄汝普, 肖久旻, 毕麟, 缪雄伟. 基于气体旁通蒸发技术的制热量提升研究[J]. 家电科技, 2022, 0(zk): 194-197.

SHAO Yanpo, HUANG Rupu, XIAO Jiumin, BI Lin, Miao Xiongwei. Research on heating enhancement based on the using of vapor-bypassed evaporation technology[J]. Journal of Appliance Science & Technology, 2022, 0(zk): 194-197.

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