2021
DOI: 10.1016/j.optlastec.2020.106539
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Influence of laser power on molten pool flow field of laser-MIG hybrid welded Invar alloy

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Cited by 24 publications
(10 citation statements)
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“…As the laser power increases to 8 kW, the workpiece is collapsed, the melt pool energy continues to move down to the collapsed area, and the loss of laser energy causes the melt pool temperature to decrease. Since the main driving force for keyhole formation is the recoil pressure of the metal vapor generated by the high-energy-density laser, the laser power is the key factor affecting the lock hole depth [29]. Figure 12 shows the evolution of the keyhole at a laser power of 7.5 kW.…”
Section: Resultsmentioning
confidence: 99%
See 1 more Smart Citation
“…As the laser power increases to 8 kW, the workpiece is collapsed, the melt pool energy continues to move down to the collapsed area, and the loss of laser energy causes the melt pool temperature to decrease. Since the main driving force for keyhole formation is the recoil pressure of the metal vapor generated by the high-energy-density laser, the laser power is the key factor affecting the lock hole depth [29]. Figure 12 shows the evolution of the keyhole at a laser power of 7.5 kW.…”
Section: Resultsmentioning
confidence: 99%
“…The multiple reflections of the laser in the keyhole promote the absorption of the laser by the keyhole. With the increase of laser power, the depth of the keyhole increases, the laser energy is delivered to the deeper layer of the workpiece, and the melt pool depth increases [29]. Figure 14 shows the variation of the molten pool depth below the keyhole w for three laser powers.…”
Section: Resultsmentioning
confidence: 99%
“…Therefore, it can be said that the HFSC technique combines the best of FSC and FSW processes, in a distinct single processing action with its own challenges, namely including parameters inherent to the integration of the integrated actions of channeling and welding, just like in other hybrid solutions such as laser-MIG hybrid welding integrating different power sources. [63] HFSC opens a new dimension in engineering design for thermal management, by using channels in lightweight materials, such as aluminum alloys, that can be used as small width and thick ribs, welded to thin and large width sheet metal of high density and expensive materials with high thermal performance, such as Cu and its alloys, as depicted in Figure 8b. Wherein combination of Al-Cu system enhances heat extraction capacity and reduces overall weight.…”
Section: Hybrid Friction Stir Channelingmentioning
confidence: 99%
“…Therefore, the retreating side of Figure 22. Microstructures of hybrid friction stir channeling (HFSC) (a) ceiling zone, [63] (b) weld zone, [63] (c) weld zone-hook like effect [51] and (d) weld zone-film like flaws. [51] Figure 23.…”
Section: Surface Features and Performancementioning
confidence: 99%
“…The wide process window with laser spot diameter of 360 or 560 μ m and welding speed of 4.5∼10 m/min can produce undercharge or hump. Yan et al 17 found that the depth of keyhole was mostly impacted by the laser power. And the increase of laser power was beneficial to obtain weld seam with larger depth-to-width ratio.…”
Section: Introductionmentioning
confidence: 99%