[1] Zhang S P, Tang X Q, Ding Y C[M]. Special processing technology, 153-154(2014).

[2] Yan C, Li L J, Li J et al. Review of surface quality study on laser sheets cutting[J]. Laser Technology, 29, 270-274(2005).

[3] Li X Y, Zeng X Y, Liu Y et al. Study of YAG laser cutting process with stainless steel sheet[J]. Chinese Journal of Lasers, 28, 1125-1129(2001).

[4] Wang L M, Tang C, Lu C X et al. Research on high power laser cutting technology of 15 mm thick 2A12 aluminum alloy[J]. Applied Laser, 41, 1017-1024(2021).

[5] Deng Q S, Tang X H, Qin Y X et al. Technological study on high power CO2 laser cutting of small hole on middle-thick steel plates[J]. Laser Technology, 32, 554-557(2008).

[6] Liu C J, Song X D, Wan Y P. Research on influence of laser cutting parameters on cutting quality of 304 stainless steel sheet[J]. Hot Working Technology, 50, 146-149(2021).

[7] Feng Q B, Zhao W C. Study on surface quality of 304 stainless steel in laser cutting process[J]. Coal Technology, 36, 296-298(2017).

[8] Wei Y F, Hu C J, Wang C M et al. Research on ultra-high power laser cutting process of Q345 carbon steel[J]. Applied Laser, 41, 22-27(2021).

[9] Hu C J, Wei Y F, Wang C M et al. Study on technology in 10 kW fiber laser cutting of 2A12 medium-thickness aluminum alloy plate[J]. Applied Laser, 40, 1092-1098(2020).

[10] Pocorni J, Powell J, Deichsel E et al. Fibre laser cutting stainless steel: fluid dynamics and cut front morphology[J]. Optics & Laser Technology, 87, 87-93(2017).

[11] Pocorni J, Powell J, Frostevarg J et al. The geometry of the cutting front created by Fibre and CO2 lasers when profiling stainless steel under standard commercial conditions[J]. Optics & Laser Technology, 103, 318-326(2018).

[12] Shin J S, Oh S Y, Park S et al. Underwater laser cutting of stainless steel up to 100 mm thick for dismantling application in nuclear power plants[J]. Annals of Nuclear Energy, 147, 107655(2020).

[13] Levichev N, Costa Rodrigues G, Vorkov V et al. Coaxial camera-based monitoring of fiber laser cutting of thick plates[J]. Optics & Laser Technology, 136, 106743(2021).

[14] Liu S H[M]. Laser materials processing, 280-285(2011).

[15] Ren N. Numerical simulation and experimental study of laser cutting NdFeB magnetic materials[D], 15-20(2020).

[16] Sun J F, Zhang Q M, Yang Z et al. Research on optimization of fiber laser cutting technology of 316L stainless steel[J]. Applied Laser, 36, 72-77(2016).

[17] Yu H. Experiments and numerical simulation about the gap width of flame cutting[D], 45-50(2017).

[18] Wang J J. Numerical simulation of the process of laser melting and cutting thick plate[D], 37-46(2014).

[19] Chen L. Simulation and experimental analysis of laser-oxygen cutting of thick mild steel plate[D], 69-80(2014).

[20] Jarosz K, Ukar E, Krödel A et al. Laser ablation and processing of polycrystalline cubic boron nitride cutting tool material[J]. The International Journal of Advanced Manufacturing Technology, 118, 785-800(2022).

[21] Saternus Z, Piekarska W, Kubiak M et al. Numerical modeling of cutting process of steel sheets using a laser beam[J]. MATEC Web of Conferences, 254, 08004(2019).

[22] Kheloufi K, Amara E, Benzaoui A. Optimization of the laser cutting process in relation to maximum cutting speed using numerical modeling[J], 38, 127-136(2017).

[23] Darwish M, Mrňa L, Orazi L et al. Numerical modeling and Schlieren visualization of the gas-assisted laser cutting under various operating stagnation pressures[J]. International Journal of Heat and Mass Transfer, 147, 118965(2020).