Analysis of the mechanical operating characteristics and resonance performance of linear compressors under variable frequency conditions

Abstract

This study investigates the electrical operating characteristics and resonance performance of a moving-magnet linear compressor under variable-frequency conditions. A three-phase permanent-magnet linear motor simulation model was established based on vector-control principles. An experimental test bench was then built to evaluate the compressor under different stroke, frequency, and load conditions. Under no-load conditions, motor efficiency decreased with increasing frequency at a fixed stroke and also decreased with increasing stroke at a fixed frequency. The motor force constant was ∼83 N/A within the main operating range. Under loaded conditions, both current and input power first decreased and then increased with frequency, while motor efficiency showed the opposite trend, reaching its maximum near the resonance frequency. At resonance, current and velocity were nearly in phase. In addition, a three-dimensional force-current-stroke map was constructed from the experimental data, and the effect of capacitive compensation on system performance was analysed. The results provide experimental support for high-efficiency zone design and control optimisation of linear compressors.

Keywords

linear compressor variable frequency operation vector control resonance frequency electrical operating characteristics

Get full access to this article

View all access options for this article.

References

Liang

. A review of linear compressors for refrigeration. Int J Refrig 2017; 84: 253–273.

Bradshaw

Groll

Garimella

. A comprehensive model of a miniature-scale linear compressor for electronics cooling. Int J Refrig 2011; 34(1): 63–73.

Sun

Zou

, et al. Characteristic analysis and energy efficiency of an oil-free dual-piston linear compressor for household refrigeration with various conditions. Energy 2023; 270: 126931.

Tang

Zou

, et al. Experimental performance of a heat pump driven by vapor injection linear compressor. Appl Therm Eng 2023; 225: 120197.

Teng

Zhu

, et al. Effective strategy of non-axisymmetric endwall contouring in a linear compressor cascade. Proc Inst Mech Eng Part G: J Aerosp Eng 2022; 236(8): 1473–1487.

Sun

Ottavy

Liu

, et al. Corner separation control by optimizing blade end slots in a linear compressor cascade. Aerosp Sci Technol 2021; 114: 106737.

Chen

Jiang

, et al. Modelling and measurement of a moving magnet linear motor for linear compressor. Energies 2020; 13(15): 4030.

Jiang

Liang

. Characteristics of a novel moving magnet linear motor for linear compressor. Mech Syst Signal Process 2019; 121: 828–840.

Lee

Song

Park

, et al. Development of the linear compressor for a household refrigerator. In: Proceedings of the international compressor engineering conference, Purdue University, West Lafayette, USA, 2000, pp.31–38.

10.

Wang

Howe

Lin

. Design optimization of short-stroke single-phase tubular permanent-magnet motor for refrigeration applications. IEEE Trans Ind Electron 2009; 57(1): 327–334.

11.

Hassan

Bijanzad

Lazoglu

. Dynamic analysis of a novel moving magnet linear actuator. IEEE Trans Ind Electron 2016; 64(5): 3758–3766.

12.

Sun

Luo

. Improvement of tubular linear oscillating actuators by using end ferromagnetic pole pieces. IEEE Trans Energy Convers 2018; 33(4): 1686–1691.

13.

Sun

Zou

, et al. Experimental assessment on operation efficiency and output characteristics of an oil-free linear compressor in a refrigeration system under various parameters. Appl Therm Eng 2024; 242: 122453.

14.

Zhu

Zhou

Meng

, et al. Corner stall control in linear compressor cascade by blended blade and endwall technique based on large eddy simulation. Phys Fluids 2021; 33(11): 115124.

15.

Zhu

Liang

, et al. A numerical model of a linear compressor for household refrigerator. Appl Therm Eng 2021; 198: 117467.

16.

Van Den Braembussche

Swevers

Van Brussel

, et al. Accurate tracking control of linear synchronous motor machine tool axes. Mechatronics 1996; 6(5): 507–521.

17.

Yao

Wang

. Adaptive robust precision motion control of high-speed linear motors with on-line cogging force compensations. In: 2007 IEEE/ASME international conference on advanced intelligent mechatronics, Zurich, Switzerland, 4–7 September 2007, pp.1–6. New York: IEEE.

18.

Fang

Chiong

, et al. Moving magnet linear compressor: operating characteristics under resonance and off-resonance frequencies. J King Saud Univ Sci 2023; 35(3): 102544.

19.

Qian

Yang

, et al. The effect of driving voltage waveforms on the efficiency of linear compressor. Appl Therm Eng 2024; 243: 122635.

20.

Zhu

Liang

, et al. A novel resonant frequency tracking technique for linear compressors. Mech Syst Signal Process 2023; 201: 110675.

21.

Lumsden

Ludbrook

Rogers Rehn

, et al. Additive manufacturing materials for structural optimisation and cooling enhancement of superconducting motors in cryo-electric aircraft. Supercond Sci Technol 2023; 36(10): 105014.

22.

Abdelmaksoud

Al-Mola

Abro

, et al. In-depth review of advanced control strategies and cutting-edge trends in robot manipulators: analyzing the latest developments and techniques. IEEE Access 2024; 12: 47672–47701.

23.

Sun

Zhao

, et al. Resonant frequency tracking of a cantilever-enhanced fiber-optic photoacoustic gas sensor based on solid absorption. Anal Chem 2025; 97(9): 5290–5296.