家用电器可燃制冷剂泄漏扩散研究进展

doi:10.19784/j.cnki.issn1672-0172.2025.99.066

摘要/Abstract

摘要： 含氟制冷剂的使用加剧了全球的温室效应,我国已经加入《基加利修正案》,并制定了新型制冷剂的替换进程。新型环境友好型制冷剂多为可燃制冷剂,研究可燃制冷剂的泄漏扩散过程有助于推进新型制冷剂的推广应用。综述了目前国内外针对R32、R290等新型环境友好型制冷剂的泄漏扩散机制和泄漏扩散实验方面的研究进展。针对可燃制冷剂的泄漏过程和扩散浓度分布情况,相关学者和研究人员进行了制冷剂泄漏扩散理论模型的探讨,并通过实验进行验证,取得了很多研究成果,揭示了可燃制冷剂的泄漏扩散机制,为使用可燃制冷剂的空调器、冷柜等家用电器的安全使用和可燃制冷剂的大范围推广提供了理论参考,对可燃制冷泄漏扩散的研究进行了展望。

关键词: 家用电器, 可燃制冷剂, 泄漏, 丙烷, 二氟甲烷

Abstract: The use of fluorinated refrigerants has intensified the global greenhouse effect. China has acceded to the Kigali Amendment and established a transition plan for new refrigerants. Most of the new environmentally friendly refrigerants are combustible, and research into their leakage and diffusion processes aids in advancing their wider application. Reviews the recent research developments on the leakage diffusion mechanisms and experiments of new environmentally friendly refrigerants like R32 and R290, both domestically and internationally. In response to the leakage processes and diffusion concentration distributions of flammable refrigerants, scholars and researchers have discussed theoretical models for refrigerant leakage and diffusion, corroborating these with experiments, and attaining numerous findings that unveil the leakage and diffusion mechanisms of flammable refrigerants. Offers a theoretical basis for the safe operation of household appliances, such as air conditioners and freezers, that utilize flammable refrigerants, and for the extensive promotion of these refrigerants. Also provides insights into the future directions of research on the leakage and diffusion of flammable refrigerants.

Key words: Household appliances, Flammable refrigerants, Leakage, propane, Difluoromethane

中图分类号:

TM925.1

王伯燕, 李欣, 张子祺, 杨双, 王超, 徐传芳, 曹焱晶. 家用电器可燃制冷剂泄漏扩散研究进展[J]. 家电科技, 2025, 0(zk): 314-318.

WANG Boyan, LI Xin, ZHANG Ziqi, YANG Shuang, WANG Chao, XU Chuanfang, CAO Yanjing. Research progress on leakage and diffusion of flammable refrigerants in household appliances[J]. Journal of Appliance Science & Technology, 2025, 0(zk): 314-318.

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