Control system of linear compressor for refrigerator

doi:10.3969/j.issn.0438-1157.2014.z2.026

CIESC Journal ›› 2014, Vol. 65 ›› Issue (z2): 175-180.DOI: 10.3969/j.issn.0438-1157.2014.z2.026

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Control system of linear compressor for refrigerator

ZOU Huiming, TANG Mingsheng, XU Hongbo, SHAO Shuangquan, TIAN Changqing

Technical Institute of Physics and Chemistry, CAS, Beijing 100190, China

Received:2014-08-21 Revised:2014-08-31 Online:2014-12-30 Published:2014-12-30
Supported by:
supported by the National Natural Science Foundation of China(51105355).

电冰箱用线性压缩机的控制系统

邹慧明, 唐明生, 徐洪波, 邵双全, 田长青

中国科学院理化技术研究所, 热力过程与节能技术北京市重点实验室, 北京 100190

通讯作者: 邹慧明
基金资助:
国家自然科学基金项目(51105355)。

Abstract

Abstract:

Three main key control technologies of linear compressor—stroke detection, top dead center (TDC) detection and performance improvement are investigated by the experimental research theoretical analysis. Based on the above control technologies, a control strategy of linear compressor for refrigerator is designed according to the control target of linear compressor for refrigerator. The coupling cooling operation results show that the control strategy can fulfill the control target well and the cooling COP of the linear compressor under the rating working condition of refrigerator is around 1.74.

Key words: linear compressor, control, kinetic, stroke detection, TDC

摘要：

通过线性压缩机的实验研究和理论分析,研究了电冰箱用线性压缩机控制系统中行程检测、上死点检测和变工况性能优化这几个关键控制技术。在此基础上,根据电冰箱用线性压缩机的控制目标,制定了适合电冰箱制冷运行的控制策略,并进行了制冷性能实验。与线性压缩机的联合运行制冷实验结果显示,基于上述控制技术的控制系统可以有效地实现线性压缩机高效可靠的制冷运行,实现电冰箱额定工况下制冷性能系数COP在1.74以上。

关键词: 线性压缩机, 控制, 动力学, 行程检测, 上死点

CLC Number:

TH457

ZOU Huiming, TANG Mingsheng, XU Hongbo, SHAO Shuangquan, TIAN Changqing. Control system of linear compressor for refrigerator[J]. CIESC Journal, 2014, 65(z2): 175-180.

邹慧明, 唐明生, 徐洪波, 邵双全, 田长青. 电冰箱用线性压缩机的控制系统[J]. 化工学报, 2014, 65(z2): 175-180.

References 16

[1]	Unger R. Development and testing of a linear compressor sized for the European market//Proceedings of International Appliance Technology Conference[C]. Purdue University, 1999:41-49
[2]	Xie Jiefei (谢洁飞),Jin Tao (金涛),Tong Shuiguang (童水光). Research status and development trend of linear compressor[J]. Fluid Machinery, 2004,32(12): 31-35
[3]	Zhang Liqin (张立钦),Zou Huiming (邹慧明),Xu Hongbao(徐洪波),et al. State of art of linear compressor for small refrigeration equipments[J].Compressor Technology(压缩机技术), 2008(5): 1-6
[4]	Lee H, Song G. Development of the linear compressor for household refrigeration//Proceedings of International Compressor Engineering Conference[C]. Purdue University, 2000: 31-38
[5]	Kim H, Roh C, Kim J, et al. An experimental and numerical study on dynamic characteristic of linear compressor in refrigeration system[J]. International Journal of Refrigeration, 2009(32): 1536-1542
[6]	Choe G, Kim K. Analysis of nonlinear dynamics in a linear compressor[J]. International Journal Series C of Japan Society of Mechanical Engineers, 2000, 43(3): 545-552
[7]	Choe G, Kim K. Theoretical and experimental analysis of nonlinear dynamics in a linear compressor[J]. Journal of Vibration and Acoustics, ASME, 2011, 124(1): 152-156
[8]	Zou Huiming, Zhang Liqin, Peng Guohong,et al. Experimental investigation and performance analysis of a dual-cylinder opposed linear compressor[J]. Journal of Mechanical Science and Technology, 2002, 25(8): 1-8
[9]	Chun T W, Ahn J R, Yoo J Y, et al. Analysis and control for linear compressor system driven by PWM inverter//The 30th Annual Conference of the IEEE[C]. Industrial Electronics Society, Busan, 2004
[10]	Huang B J, Chen Y C. System dynamics and control of a linear compressor for stroke and frequency adjustment[J]. Journal of Dynamic Systems Measurement and Control ,2002, 124(1):176-182
[11]	Heo K B, Lee H K,Lee C W, et al. Control of a linear compressor//International Conference on Compressors and Their Systems[C]. London, 2003
[12]	Sung J, Lee C, Kim G, et al. Sensorless control for linear compressors[J]. International Journal of Applied Electromagnetics and Mechanics,2006, 24: 273-286
[13]	Yang Y, Huang B. Fuzzy control on the phase and stroke of a linear compressor of a split-stirling cryocooler[J]. Cyogenics, 1998, 38(2): 231-238
[14]	Lin Z, Wang J, Howe D. A resonant frequency tracking technique for linear vapor compressors//Proceedings of IEEE International Electric Machines and Drives Conference[C]. 2007: 370-375
[15]	GB 5773—2004
[16]	Redlich R, Unger R, Walt N. Linear compressor: moter configuration, modulation and systems//International Compressor Engineering Conference[C]. Purdue University, 1996: IN 47907-1077

Control system of linear compressor for refrigerator

电冰箱用线性压缩机的控制系统

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