RESEARCH STATUS OF PHYSICAL FIELD-ASSISTED LASER WELDING
Volume 1, Issue 2, Pp 11-15, 2023
DOI:10.61784/wjmp231278
Author(s)
Lana Susac
Affiliation(s)
Department of Physics, Faculty of Science, University of Zagreb, Zagreb, Croatia.
Corresponding Author
Lana Susac
ABSTRACT
To review the current research status at home and abroad of different physical field -assisted laser welding, looking forward to the future of physical field-assisted laser welding technology The future direction of development. Method Discussion Electric Field, magnetic field, ultrasonic field and other different physical fields on the laser welding process Mechanism of influence, right than not Same thing Advantages and Disadvantages of Physical Field Effect. Results and conclusions based on the development status of physical field-assisted laser welding, refer to out of work Art optimization, equipment integration, Challenges faced by theoretical foundations and other aspects, and looked forward to the future development trend of this technology.
KEYWORDS
Electromagnetic field; LASER welding; Development trend
CITE THIS PAPER
Lana Susac. Research status of physical field-assisted laser welding. World Journal of Mathematics and Physics. 2023, 1(2): 11-15. DOI:10.61784/wjmp231278.
REFERENCES
[1] Zhai Lulu, Ban Chunyan, Zhang Junwei. Electromagnetic field during laser welding Research status of application mechanism. Thermal Processing Technology, 2019, 48(15): 12-17, 21.
[2] Yao Yan Health, king garden Garden, Li Xiu Yu. Review of laser hybrid welding technology. Thermal Processing Technology, 2014, 43(9):1 6-20, 24.
[3]Li Xueyuan. The effect of external electric field on low power pulse Rush YAG laser + Influence of TIG arc hybrid welding. Dalian:Dalian University of Technology, 2012.
[4]Xiao Rongshi, Zuo Tiechuan, AMBROSY G, wait. Using filler wire electricity flow Aluminum alloy Gold CO 2 excitement Light weld catch. weld catch study report, 2006, 27(5):9-12, 113.
[5] XIAO RS, ZUOTC, LEIMSER M, et al. Hybrid Nd: YAGlaserbeam welding of aluminum in addition with an electric current//Proc. SPIE5629, Lasersin Material Processing and Manufacturing II, 2005: 195-201. https://doi.org/10.1117/12.574682.
[6]TSEHC, MAN HC, YUET M. Effectofelectric field on p lasma control during CO2 laser welding. OpticsandLasersinEngineering, 2000, 33(3):181-189.
[7] Li Xiaoquan, Yang Zonghui, Zhao Zhi country. Auxiliary external electric field between slag and metal improves welding Analysis of connection process stability. Journal of Welding, 2014, 35 (1):17- 20, 113-114.
[8]Yao Jianhua. Research status and prospects of laser composite manufacturing technology. electricity Processing and Mold, 2017(S1):4 -11.
[9] CHEN R, WANGC M, JIANGP, et al. Effectof axialmagnetic field in the laser beam welding of stainlesssteel to aluminum alloy. Materials & Design, 2016, 109: 146-152.
[10]LI M, XUJJ, HUANGY, et al. Improving key hole stability b y external magnetic field in full penetration laser welding. JOM, 2018, 70(7):1261-1266.
[11]ZHAN X H, ZHOUJJ, SUN W H, et al. Effect of external applied steady magnetic field on the morpholo gy of laser welding joint of 4-mm 2024 aluminum alloy. Applied PhysicsA, 2017, 123: 106.
[12]Zhang Xun, Li Ruoyang, Zhao Zeyang, etc. Applying an external longitudinal magnetic field to the laser Morphology and microstructure of MIG composite welded joints shadow ring. middle China Laser, 2017, 44(8):0802008.
[13] Ding Hao, Xu Jiale, Tan Wensheng, etc. Magnetic field laser welding of steel/aluminum dissimilar gold genus weld seam sex able of film ring. middle country exciting Light, 2017, 44(9):0902003.
[14] Wang Yunpeng, Shi Yan. Effect of magnetic field on laser welding structure and corrosion resistance of industrial pure nickel. Laser Technology, 2019, 43(1):19-24.
[15] Zhao Zeyang, Mi Gao Yang, Zhang Xun, etc. Applying external magnetic field to stainless steel laser hot wire welded film ring. excited Light technology Technology, 201 7, 41(2):270-274.
[16]FRITZSCHE A, AVILOV V, GUMENYUK A, et al. High power laserbeam welding of thick walled ferromagnetic steels with electromagnetic weld pool support. Physics Procedia, 2016, 83: 362-372.
[17]Wang Yunpeng. Effect of electro - magnetic field on the microstructure and properties of industrial pure nickel laser welding. Changchun:Changchun University of Science and Technology, 20 18.
[18] AVILOV V, SCHNEIDER A, LAMMERS M ,et al. Electromagneticcontroloftheweld pooldy- namicsin p artial p enetrationlaserbeam welding of aluminiumalloys. JournalofIronandSteelRe- search(International), 2012, 19(S1): 233-236.
[19]CHENJC, WEI Y H, ZHAN X H, et al. Influence of magnetic fieldorientationon molten pool dynamicsduring magnet-assisted laser buttweld- ing of thick aluminumalloy p lates. Optics and Laser Technology, 2018, 104: 148-158.
[20]ZHOU SY, MA G Y, WU DJ, et al. Ultrasonic vibrationassistedlaserwelding ofnickel-basedal-lo y and Austenitestainless steel. Journal ofManufacturingProcesses, 2018, 31: 759-767.
[21] KIMJS, WATANABET, YOSHIDA Y. Ultra-sonicvibrationaidedlaser welding of Al allo ys:improvement oflaserwelding-quality. JournalofLaserApplications, 1995, 7(1): 38-46.
[22] VENKANNAH S, MAZUMDERJ. The effect of ultra sound on the micro hardness and nano hardness of laser weldsinmild steel//Proceedings of the World Congress on Engineering(Ⅱ). London:2009: 1653-1657.
[23] Zhu Zongtao, Zhu Quanchao, Li Yuanxing, etc. Microstructure and mechanical properties of laser-MIG hybrid welding of A7N01 aluminum alloy assisted by ultrasonic vibration. Journal of Welding, 2016, 37(6): 80-84, 132-133.
[24] LEI ZL, BIJ, LI P, et al. Meltflow and g rain refining inultrasonicvibration assisted laser welding processofAZ31B magnesium alloy. Optics& Laser Technology, 2018, 108: 409-417.
[25] LEI ZL, BIJ, LI P, et al. Analysis on welding characteristic ultrasonic assisted laser welding of AZ31B magnesium alloy. Optics & Laser Technology, 2018, 105: 15-22.
[26] Liu Haodong, Hu Fangyou, Cui Aiyong, etc. Welding thermal cycle test based on ultrasonic cross-state treatment. Journal of Welding, 2015, 36(8): 13-17, 113-114.
[27] LIUJ, ZHU HY, LIZ, et al. Effect of ultrasonic power on porosity, micro structure, mechanical properties of the aluminum alloy joint by ultrasonic assisted laser-MIG hybrid welding. Optics & Laser Technology, 2019, 119: 105619.
[28] Wang Liang, Song Shiying, Hu Yong, et al. Research on the regulation of solidification structure of laser cladding layer by the synergistic effect of electromagnetic composite field. China Laser, 2015, 42 (Special Issue): s103005.
[29] LINDENAU D, AMBROSY G, BERGER P, et al. Effects of magnetically supported laser beam welding of aluminum alloys//20stInternational Congresson Applications of Lasers and Electro-Optics. Jackson wile: 2001: 168-178.
[30]AMBROSY G, BERGER P, HUEGEL H, et al.The use of electromagnetic body forces to enhance the quality of laser welds//XIV International Symposium on Gas Flow, Chemical Lasers, and High Power Lasers. Bellingham: International Society for Opticsand Photonics. 2003: 596-600.
[31]SCHNEIDER A, AVILOV V, GUMENYUK A ,et al. Laserbeam welding of aluminum alloys under the influence of an electromagnetic field. Physics Procedia, 2013, 41: 4-11.
[32]FRITZSCHE A, HILGENBERG K, TEICH-MANN F, et al. Improved degassing in laser beam welding of aluminum diecasting by an electromagnetic field. Journal of Materials Processing Technology, 2018, 253: 51-56.