Performance Analysis for Discoid Springs and Components of Linear Compressors

doi:10.3969/j.issn.1004-132X.2022.08.004

China Mechanical Engineering ›› 2022, Vol. 33 ›› Issue (08): 908-914.DOI: 10.3969/j.issn.1004-132X.2022.08.004

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Performance Analysis for Discoid Springs and Components of Linear Compressors

CHEN Hongyue1,2,3;ZHANG Zhanli1;LIU Xianyang1;CHEN Hongyan1;HUANG Xinyu1;WEI Yajing4

1.College of Mechanical Engineering,Liaoning Technical University,Fuxin,Liaoning,123000
2.Dynamic Research for High-end Complete Integrated Coal Mining Equipment and Big Data Analysis Center,China National Coal Association,Fuxin,Liaoning,123000
3.Combined Mining Technology and Equipment Engineering National Research Center,Fuxin,Liaoning,123000
4.Fuxin City Industrial Technology Research Institute,Fuxin,Liaoning,123000

Online:2022-04-25 Published:2022-05-19

线性压缩机盘簧及组件性能分析

陈洪月1,2,3;张站立1;刘先阳1;陈洪岩1;黄鑫宇1;魏雅静4

1.辽宁工程技术大学机械工程学院，阜新，123000
2.中国煤炭工业协会高端综采成套装备动力学测试与大数据分析中心，阜新，123000
3.矿山液压技术与装备国家工程研究中心，阜新，123000
4.阜新市产业技术研究院，阜新，123000

通讯作者: 张站立(通信作者)，男，1994年生，硕士研究生。研究方向为机械设计及理论。E-mail：zhanlistudy@126.com。
作者简介:陈洪月，男，1982年生，教授、博士研究生导师。研究方向为机械系统结构优化设计。发表论文53篇。E-mail：chyxiaobao@126.com。
基金资助:
国家自然科学基金(51874157)；
辽宁省教育厅基础研究项目(LJ2020JCL026)；
辽宁省自然科学基金(2019-MS-161)；
2019年度辽宁省高等学校创新人才（理）项目(LR2019030)

Abstract

Abstract: The existing leaf springs for compressors, which were used in a large number, had low stiffness, so a discoid spring was designed. Stiffness performance of discoid springs and flexible leaf springs were compared by FEM(finit element melhod), and 3 arm shapes with better performance were chosen from 8 different arm shapes of discoid springs. 9 different layout modes of the spring group were analyzed and it is found that the discoid spring placed between two flexible leaf springs with equal thickness show better performance. Response surface objective optimization method was used to optimize the distance of the springs in spring groups. After optimization, the radial stiffness is increased as 37.5%. The stiffness of the optimized spring group were tested and compared with the FEM results.

Key words: linear compressor, discoid spring, layout mode, stiffness

摘要： 现有压缩机用板弹簧刚度小、使用数量多，因此设计了一种盘簧。采用有限元法（FEM）对比了盘簧和柔性板弹簧的刚度，并从8种不同臂形的盘簧中确定了3种性能较优的臂形；分析了弹簧组的9种布置方式，发现将盘簧放置在两等厚柔性板弹簧之间时支撑性能较好；采用响应面目标优化法对弹簧组间距进行优化，优化后的径向刚度增大了37.5%；对优化后的弹簧组刚度进行了实验测试，并将其与FEM结果进行了对比。

关键词: 线性压缩机, 盘簧, 布置方式, 刚度

CLC Number:

TH122
TH135

CHEN Hongyue, ZHANG Zhanli, LIU Xianyang, CHEN Hongyan, HUANG Xinyu, WEI Yajing. Performance Analysis for Discoid Springs and Components of Linear Compressors[J]. China Mechanical Engineering, 2022, 33(08): 908-914.

陈洪月, 张站立, 刘先阳, 陈洪岩, 黄鑫宇, 魏雅静. 线性压缩机盘簧及组件性能分析[J]. 中国机械工程, 2022, 33(08): 908-914.

References

［1］BRADSHAW C R, GROLL E A, GARIMELLA S V. Linear Compressors for Electronics Cooling:Energy Recovery and the Useful Benefits［C］∥Proceedings of International Compressor Engineering Conference. Purdue, 2012:1-10.
［2］LAMANTIA M, CONTARINI A, GIOVANNI S. Numerical and Experimental Analysis of a Linear Compressor［C］∥Proceedings of International Compressor Engineering Conference. Purdue, 2002：C23-2.
［3］BANSAL P, VINEYARD E, ABDELAZIZ O. Advances in Household Appliances—a Review［J］. Applied Thermal Engineering:Design, Processes, Equipment, Economics， 2011,31(17/18):3748-3760.
［4］LIANG K, STONE C R, HANCOCK W, et al. Comparison between a Crank-drive Reciprocating Compressor and a Novel Oil-free Linear Compressor［J］. International Journal of Refrigeration, 2014,45:25-34.
［5］TROLLIER T, RAVEX A, CRESPI P, et al. High Capacity Flexure Bearing Stirling Cryocooler On-board the ISS［C］∥Cryocoolers 12. Boston, 2002:31-35.
［6］MEYMIAN N Z, CLARK N N, MUSHO T, et al. An Optimization Method for Flexural Bearing Design for High-stroke High-frequency Applications［J］. Cryogenics, 2018,95:82-94.
［7］WONG T, PAN R, JOHNSON A. Novel Linear Flexure Bearing［C］∥Cryocoolers 7. New York:Plenum Press, 1992:675-698.
［8］MARQUARDT E, RADEBAUGH R, KITTEL P. Design Equations and Scaling Laws for Linear Compressors with Flexure Springs［C］∥Cryocoolers 7. Plenum Press, New York, 1992:783-804.
［9］AMOEDO S, THEBAUD E, GSCHWENDTNER M, et al. Novel Parameter-based Flexure Bearing Design Method［J］. Cryogenics, 2016,76:1-9.
［10］ZHOU W, WANG L, GAN Z, et al. The Performance Comparison of Oxford and Triangle Flexure Bearings［J］. AIP Conference Proceedings, 2012, 1434:1149-1156.
［11］RAJESH V R, KUZHIVELI B T. Modelling and Failure Analysis of Flexure Springs for a Stirling Cryocooler［J］. Journal of Engineering Science and Technology, 2017, 12(4):888-897.
［12］陈曦，刘颖，袁重雨，等.基于费马曲线的柔性板弹簧的理论与试验研究［J］.机械工程学报，2011，47（18）:130-136.
CHEN Xi, LIU Ying, YUAN Chongyu, et al. Theory and Experimental Study on Flexure Spring Based Fermat Curve［J］. Journal of Mechanical Engineering, 2011, 47(18):130-136.
［13］高威利，颜鹏达，陈国邦.用于高频脉管制冷机的涡旋板弹簧的优化设计［J］.低温工程，2009（1）：5-8.
GAO Weili, YAN Pengda, CHEN Guobang. Optimization Design of Spiral Flexure Spring for High-frequency Pulse Tube Cryocooler［J］. Cryogenics, 2009(1):5-8.
［14］陈楠.大冷量斯特林制冷机用动磁式直线压缩机关键部件及整机性能研究［D］.上海：上海交通大学，2007.
CHEN Nan. Theoretical and Experimental Study of the Moving-magnet Linear Compressor Stirling Refrigerator with Large Cooling Capacity ［D］. Shanghai：Shanghai Jiao Tong University, 2007.
［15］周伟楠，朱海峰，陈雷，等.微型斯特林制冷机用柔性板弹簧性能分析［J］.低温工程，2019（6）：12-18.
ZHOU Weinan, ZHU Haifeng, CHEN Lei, et al. Performance Analysis of Flexure Spring for Micro-miniature Cryocooler［J］. Cryogenics, 2019(6):12-18.
［16］陈楠，陈曦，吴亦农，等.涡旋柔性弹簧型线设计及有限元分析［J］.中国机械工程，2006，17(12)：1261-1265.
CHEN Nan, CHEN Xi, WU Yinong, et al．Design and Finite Element Analysis of Spiral Flexure Spring［J］. China Mechanical Engineering, 2006,17(12):1261-1265.
［17］曹广亮，陈曦，秦彤彤，等.柔性板弹簧组件及对间隙密封的影响［J］.真空与低温，2016(22):306-310.
CAO Guangliang, CHEN Xi, QIN Tongtong, et al. Analysis of Flexible Spring Assembly and Its Effect on Clearance Seal［J］. Vacuum & Cryogenics, 2016(22):306-310.
［18］张凯，陈军，李海英，等.线性压缩机用柔性弹簧组件支撑性能研究［J］.红外技术，2020，42(2):198-203.
ZHANG Kai, CHEN Jun, LI Haiying, et al. Performance Analysis of Flexure Bearing Component Radial Stiffness for Linear Compressors［J］. Infrared Technology, 2020, 42(2):198-203.
［19］陈洪月，张站立，林青竹.制冷线性压缩机弹簧组件的设计与研究［J］.中国机械工程，2021，32(12):1449-1455.
CHEN Hongyue, ZHANG Zhanli, LIN Qingzhu. Design and Research of Refrigeration Linear Compressor Spring Assembly［J］. China Mechanical Engineering,2021, 32(12):1449-1455.
［20］AMOEDO S, THEBAUD E, GSCHWENDTNER M, et al. Novel Parameter-based Flexure Bearing Design Method［J］. Cryogenics, 2016,76:1-9.
［21］MALPANI S, YENARKAR Y, DESHMUKH S, et al. Design of Flexure Bearing for Linear Compressor by Optimization Procedure Using FEA［J］. International Journal of Engineering Science & Technology, 2012, 4(5):1991-1999.

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Performance Analysis for Discoid Springs and Components of Linear Compressors

线性压缩机盘簧及组件性能分析

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