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Laser & Optoelectronics Progress, Volume. 59, Issue 17, 1714003(2022)

Effect of Dual-Beam Energy Ratio on Microstructure and Properties of Q355ND Steel Laser-MAG Hybrid Welding Joint

Yan Yin1、*, Xiao Zhang1, Mengzhi Xiao2, Yan Gong1, Wei Zhou1, and Ruihua Zhang2,3
Author Affiliations
  • 1State Key Laboratory of Advanced Processing and Recycling of Nonferrous Metals, Lanzhou University of Technology, Lanzhou 730050, Gansu , China
  • 2China Iron & Steel Research Institute Group, Beijing , 100081, China
  • 3Yangjiang Hardware Knife Cut Industrial Technology Research Institute, Yangjiang 529533, Guangdong , China
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    AbstractGet PDF(in Chinese)
    Figures&Tables (15)
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    References (18)
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    Figures & Tables(15)
    Microstructure of base metal

    Fig. 1. Microstructure of base metal

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    Schematic diagram of dual-beam laser-MAG hybrid welding

    Fig. 2. Schematic diagram of dual-beam laser-MAG hybrid welding

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    Energy ratio of dual-beam laser

    Fig. 3. Energy ratio of dual-beam laser

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    Schematic of the groove

    Fig. 4. Schematic of the groove

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    Schematic diagram of microhardness test position of weld cross section

    Fig. 5. Schematic diagram of microhardness test position of weld cross section

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    Relationship between equilibrium phase and temperature of welding materials. (a) Q355ND; (b) ER50-6

    Fig. 6. Relationship between equilibrium phase and temperature of welding materials. (a) Q355ND; (b) ER50-6

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    XRD patterns of different regions of welded joints

    Fig. 7. XRD patterns of different regions of welded joints

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    Relationship between weld penetration depth, weld width, and hybrid welding energy ratio

    Fig. 8. Relationship between weld penetration depth, weld width, and hybrid welding energy ratio

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    Macro morphology of weld and cross section. (a) Front morphology; (b) back morphology; (c) cross section of joint

    Fig. 9. Macro morphology of weld and cross section. (a) Front morphology; (b) back morphology; (c) cross section of joint

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    Microstructure of weld zone and heat affected zone. Main arc action zone (a) weld center, (b) coarse grain zone, (c) fine grain zone, and (d) incomplete recrystallization zone; main laser action zone (e) weld center, (f) coarse-grained zone, (g) fine-grained zone, and (h) incomplete recrystallization zone

    Fig. 10. Microstructure of weld zone and heat affected zone. Main arc action zone (a) weld center, (b) coarse grain zone, (c) fine grain zone, and (d) incomplete recrystallization zone; main laser action zone (e) weld center, (f) coarse-grained zone, (g) fine-grained zone, and (h) incomplete recrystallization zone

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    Element distributions in the region near the fusion line. (a) Photo of the fusion line near the main arc action zone; (b) element distribution of Fig. (a); (c) photo of the fusion line near the main laser action zone; (d) element distribution of Fig. (c)

    Fig. 11. Element distributions in the region near the fusion line. (a) Photo of the fusion line near the main arc action zone; (b) element distribution of Fig. (a); (c) photo of the fusion line near the main laser action zone; (d) element distribution of Fig. (c)

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    Relationship between microhardness of welded joint and distance from weld center

    Fig. 12. Relationship between microhardness of welded joint and distance from weld center

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    • Table 1. Chemical composition of Q355ND steel and ER50-6 welding wires

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      Table 1. Chemical composition of Q355ND steel and ER50-6 welding wires

      MaterialMass fraction /%
      CSiMnPSNiCrCuFe
      Q355ND0.1610.2321.4800.0140.0010.0060.0160.009Bal.
      ER50-60.0800.8601.4200.0120.0110.0170.0280.125Bal.

    • Table 2. Parameters of dual-beam laser-MAG hybrid welding

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      Table 2. Parameters of dual-beam laser-MAG hybrid welding

      Laser power /kWArc current /AWelding voltage /VWelding speed /(m·min-1Flow rate of shielding gas /(L·min-1Heat sources distance /mmDefocus amount /mmWelding process
      1232526.50.7203+5Surfacing
      2332526.50.7203-2Butt welding

    • Table 3. Macro morphology and related data of weld cross section under different energy ratios

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      Table 3. Macro morphology and related data of weld cross section under different energy ratios

      ParameterEnergy ratio
      0.250.380.50.630.75
      Weld cross section
      Width /mm19.5619.6919.4819.2019.16
      Penetration depth /mm17.9716.1215.4716.1018.15
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    Yan Yin, Xiao Zhang, Mengzhi Xiao, Yan Gong, Wei Zhou, Ruihua Zhang. Effect of Dual-Beam Energy Ratio on Microstructure and Properties of Q355ND Steel Laser-MAG Hybrid Welding Joint[J]. Laser & Optoelectronics Progress, 2022, 59(17): 1714003

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    Paper Information

    Category: Lasers and Laser Optics

    Received: Nov. 9, 2021

    Accepted: Dec. 27, 2021

    Published Online: Aug. 22, 2022

    The Author Email: Yan Yin (yinyan@lut.cn)

    DOI:10.3788/LOP202259.1714003

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology