电动汽车CO2空调涡旋压缩机变工况工作特性

doi:10.3969/j.issn.1674-8484.2023.04.011

摘要/Abstract

摘要：

为了提升电动汽车续航里程，研究了CO₂空调系统变工况运行性能及涡旋压缩机工作特性。构建了耦合涡旋压缩机一维通流模型的跨临界CO₂空调系统的性能预测模型，并利用试验数据校核了模型有效性。对比了压缩机简单模型与通流模型变工况条件下对系统性能预测的差异，分析了涡旋压缩机吸气预压缩及排气非对称流动的变化规律。结果表明：变工况工作条件下，用恒定效率的压缩机简单模型所预测的系统工作特性指数（系统制冷量与压缩机功耗之比），比用一维通流模型，最多高20%；压缩机吸气真空度是影响吸气预压缩程度的主要因素，压缩机转速从2 500 r/min增至6 000 r/min，吸气预压缩程度增加1.92%，容积效率提高4.72%；排气口通流面积变化主导排气腔压力非对称分布，减小压缩机排气腔压力非对称度，有利于提高压缩机等熵效率。

关键词: 电动汽车, 续航里程, 二氧化碳空调, 涡旋压缩机, 工作特性, 通流模型

Abstract:

In order to increase the driving range of electric vehicles, the operating performances of the air conditioning system under variable conditions and the functional characteristics of the scroll compressor were investigated. The performance prediction model of a trans-critical CO₂ heat pump air conditioning system coupled with a one-dimensional flow model of a scroll compressor was constructed, and the validity of the model was verified by experimental data. The differences in system performance prediction under variable operating conditions between the simplified compressor model the and one-dimensional flow model were compared, and the variation characteristics of the suction pre-compression and the asymmetric flow in the discharge process were analyzed. The results show that with a constant efficiency, the system operating characteristics index (the ratio of the system cooling capacity to the compressor power consumption) predicted by the simple compressor model, is up to 20% higher than that by the one-dimensional flow model. The compressor suction vacuum degree is the main factor affecting the degree of suction pre-compression. As the compressor speed increases from 2 500 r/min to 6 000 r/min, the degree of suction pre-compression increases by 1.92%, and the volume efficiency increases by 4.72%. The change in the throughflow area of the discharge port dominates the asymmetric pressure distribution in the discharge chamber. The reduction of the asymmetric degree of the discharge chamber pressure is beneficial to improve the compressor isentropic efficiency.

Key words: electric vehicles, driving range, CO₂ air-conditioners, scroll compressors, operating characteristics, throughflow model

中图分类号:

U463.85

安钟衍, 宋盼盼, 鲁振博, 郑思宇, 魏名山, 诸葛伟林, 张扬军. 电动汽车CO₂空调涡旋压缩机变工况工作特性[J]. 汽车安全与节能学报, 2023, 14(4): 488-495.

AN Zhongyan, SONG Panpan, LU Zhenbo, ZHENG Siyu, WEI Mingshan, ZHUGE Weilin, ZHANG Yangjun. Operating characteristics under variable conditions of a scroll-compressor in CO₂ air-conditioning-system for electric vehicle[J]. Journal of Automotive Safety and Energy, 2023, 14(4): 488-495.

图/表 15

参考文献 20

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部件	类型	部件参数
气冷器	单层微通道翅片管换热器	350 mm×550 mm×20 mm，管程数3，总管27，单管内流道10，管横截面积2.34 mm²。
蒸发器	双层平行流换热器	200 mm×265 mm×30 mm，管程数3，总管28，单管内流道1，管横截面积18.2 mm²。
回热器	套管式换热器	管长1.2 m，外径30 mm，内径10 mm。

部件	类型	部件参数
气冷器	单层微通道翅片管换热器	350 mm×550 mm×20 mm，管程数3，总管27，单管内流道10，管横截面积2.34 mm²。
蒸发器	双层平行流换热器	200 mm×265 mm×30 mm，管程数3，总管28，单管内流道1，管横截面积18.2 mm²。
回热器	套管式换热器	管长1.2 m，外径30 mm，内径10 mm。

工况点	温度点位置	T / K		相对误差/%
工况点	温度点位置	仿真	试验	相对误差/%
1	压缩机进口	300.7	302.6	0.63
2	压缩机出口	389.7	387.8	-0.49
3	气冷器出口	310.4	313.4	0.96
4	回热器出口	299.2	306.1	2.25
5	毛细管出口	273.9	276.5	0.94
6	蒸发器出口	273.8	275.4	0.58
7	气冷器空气侧入口	305.5	305.5	0.00
8	气冷器空气侧出口	319.4	314.7	-1.49
9	蒸发器空气侧入口	307.3	299.8	-2.50
10	蒸发器空气侧出口	273.9	278.5	1.65

工况点	温度点位置	T / K		相对误差/%
工况点	温度点位置	仿真	试验	相对误差/%
1	压缩机进口	300.7	302.6	0.63
2	压缩机出口	389.7	387.8	-0.49
3	气冷器出口	310.4	313.4	0.96
4	回热器出口	299.2	306.1	2.25
5	毛细管出口	273.9	276.5	0.94
6	蒸发器出口	273.8	275.4	0.58
7	气冷器空气侧入口	305.5	305.5	0.00
8	气冷器空气侧出口	319.4	314.7	-1.49
9	蒸发器空气侧入口	307.3	299.8	-2.50
10	蒸发器空气侧出口	273.9	278.5	1.65

电动汽车CO₂空调涡旋压缩机变工况工作特性

Operating characteristics under variable conditions of a scroll-compressor in CO₂ air-conditioning-system for electric vehicle

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