[1] Ling Y, Zhao L H, Lin X et al. Discussion of improvement method of electrical contacts on high voltage disconnector[J]. High Voltage Apparatus, 46, 101-105(2010).
[2] Qian B G, Geng H R, Guo Z Q et al. Development and application of electrical contact materials[J]. Materials for Mechanical Engineering, 28, 7-9(2004).
[3] Wang R J, Wang J B, Song Y K et al. Research and development of high-voltage and vacuum copper based contact materials[J]. Electrical Engineering Materials, 15-18(2014).
[4] Du Z M, Wang J B, Fu C et al. The current situation and application of cladding technology in the copper based electrical contact materials[J]. Electrical Engineering Materials, 30-34(2009).
[5] Han Y J, Zhou X P. Study on the microstructure and wear resistance of flame sprayed high entropy alloy reinforced copper-based composite coatings[J]. Materials Protection, 54, 18-23(2021).
[6] Chen S Y, Wang J F, Liu C S et al. Particle reinforced Co-based composite alloy coating produced by laser inducing in situ synthesis on the surface of copper alloy[J]. Acta Materiae Compositae Sinica, 25, 126-130(2008).
[7] Wang H T, Li C J, Yang G J. Influence of hard phase on the properties of cold-sprayed FeAl intel-metallic compound coatings[J]. Materials Protection, 43, 90-94, 117(2010).
[8] Chen B X, Chen W. Microstructure and friction property of cold-sprayed Al-25% Al2O3 coating on the surface of AZ80 magnesium alloy for automobile[J]. Materials Protection, 52, 44-47(2019).
[11] Yang K, Li W Y. Research on bonding characteristics of particles in cold spraying Cu/Ni/Al composite coating[J]. Welded Pipe and Tube, 41, 15-20(2018).
[12] Ma G L, Kong L Y, Li T F et al. Microstructure of copper particle deposited on aluminum by cold spray[J]. Rare Metal Materials and Engineering, 47, 1166-1173(2018).
[14] Yang L J, Li Z X, Huang C L et al. Producing hard material coatings by laser-assisted cold spray: a technological review[J]. Materials Review, 32, 412-417, 426(2018).
[15] Sun J Y, Yan Y L, Li B et al. Comparative study on cavitation-resistance and mechanism of stellite-6 coatings prepared with supersonic laser deposition and laser cladding[J]. Chinese Journal of Lasers, 48, 1002118(2021).
[18] Zhang G, Zhang J, Li B et al. Influence of laser irradiation on compactness and wear resistance of Ti6Al4V coating prepared by supersonic laser deposition[J]. Acta Optica Sinica, 41, 1414002(2021).
[20] Yang L J, Li Z H, Li B et al. Microstructure and deposition mechanism of Ni60 coatings prepared by supersonic laser deposition[J]. Chinese Journal of Lasers, 42, 0306005(2015).
[26] Li S Y, Li A J, Dai D et al. Preparation, properties and application of graphene/Cu composite materials[J]. Journal of Functional Materials, 48, 9043-9051(2017).
[27] Zhang M J, Zhu S W, Yu J F et al. Development of graphite/copper matrix composites[J]. Foundry Technology, 38, 2565-2570, 2578(2017).
[28] Babu R V, Kanagaraj S. Thermal, electrical and mechanical characterization of microwave sintered copper/carbon nanotubes (CNT) composites against sintering duration, CNT diameter and its concentration[J]. Journal of Materials Processing Technology, 258, 296-309(2018).
[29] Wu L J, Wang W L, Li B et al. Influence of diamond particle size and content on the microstructure and properties of diamond/Cu composite coating prepared by supersonic laser deposition[J]. Surface Technology, 48, 40-46(2019).
[30] Wang J, Guo L N, Lin W M et al. The effects of graphene content on the corrosion resistance, and electrical, thermal and mechanical properties of graphene/copper composites[J]. New Carbon Materials, 34, 161-169(2019).
[32] Huang X J, Wu L J, Li B et al. Microstructure characterization and tribological properties evaluation on WC/Cu composite coating prepared by supersonic laser deposition[J]. Journal of Mechanical Engineering, 56, 78-85(2020).
[33] Wang J J, Tian K, Chen Z J et al. Microstructure and wear resistance of graphite/Cu composite coating prepared by supersonic laser deposition[J]. Chinese Journal of Lasers, 48, 1802015(2021).