Real time monitoring of laser beam welding keyhole depth by laser interferometry

Blecher, J. J.; Galbraith, Christopher M.; Vlack, C. Van; Palmer, Todd; Fraser, James M.; Webster, Paul J. L.; DebRoy, T.

doi:10.1179/1362171814y.0000000225

Cited by 45 publications

(8 citation statements)

References 21 publications

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“…The ICI signature observed in this processing regime is consistent with ICI measurements taken of bead-on-plate laser keyhole welding processes (Blecher et al, 2014). The existence of a vapor channel during processing allows imaging beam penetration below the substrate level and subsequent measurement of keyhole depth.…”

Section: Varying Process Power Regimessupporting

confidence: 75%

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In situ morphology-based defect detection of selective laser melting through inline coherent imaging

Kanko

Sibley

Fraser

2016

Journal of Materials Processing Technology

164

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Section: Varying Process Power Regimessupporting

confidence: 75%

“…Work by Blecher et al (2014) demonstrated the ability of ICI to measure laser keyhole depths in a range of metals, including DH36 steel, 304 stainless steel, Inconel 690, Ti-6Al-4V, and 2219 aluminum alloy. Webster et al (2014) exploited the utility of ICI for feedback control in high-power laser welding applications.…”

Section: Introductionmentioning

confidence: 99%

In situ morphology-based defect detection of selective laser melting through inline coherent imaging

Kanko

Sibley

Fraser

2016

Journal of Materials Processing Technology

164

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“…Thus, for the joining of complex components, traditional fusion welding techniques still hold considerable importance [1,2], as these processing routes allow for reasonable joint integrity. Fusion welding processes include the older-type arc-welding methods such as TIG, MIG and laser-arc hybrid welding [3][4][5], and newer beam-welding methods such as laser and electron-beam [6]. The beam processes enable the heat source to become more focused, allowing the molten pool region to form a narrower, deeper weld.…”

Section: Introductionmentioning

confidence: 99%

Keyhole formation and thermal fluid flow-induced porosity during laser fusion welding in titanium alloys: Experimental and modelling

et al. 2017

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High energy-density beam welding, such as electron beam or laser welding, has found a number of industrial applications for clean, high-integrity welds. The deeply penetrating nature of the joints is enabled by the formation of metal vapour which creates a narrow fusion zone known as a "keyhole". However the formation of the keyhole and the associated keyhole dynamics, when using a moving laser heat source, requires further research as they are not fully understood. Porosity, which is one of a number of process induced phenomena related to the thermal fluid dynamics, can form during beam welding processes. The presence of porosity within a welded structure, inherited from the fusion welding operation, degrades the mechanical properties of components during service such as fatigue life. In this study, a physics-based model for keyhole welding including heat transfer, fluid flow and interfacial interactions has been used to simulate keyhole and porosity formation during laser welding of Ti-6Al-4V titanium alloy. The modelling suggests that keyhole formation and the time taken to achieve keyhole penetration can be predicted, and it is important to consider the thermal fluid flow at the melting front as this dictates the evolution of the fusion zone. Processing 2 induced porosity is significant when the fusion zone is only partially penetrating through the thickness of the material. The modelling results are compared with high speed camera imaging and measurements of porosity from welded samples using X-ray computed tomography, radiography and optical micrographs. These are used to provide a better understanding of the relationship between process parameters, component microstructure and weld integrity.

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“…Up to now, OCT was successfully used for welding quality control particularly for online high speed profiling of keyhole depth [4]. By implementing the principles and algorithms of the WELDEYE software platform, optimally adapted to the OCT system, fast and exact estimation of the welding location, the maximum keyhole depth which gives an evidence about the power of the processing laser, and the detection of the quality of the resulted weld are possible.…”

Section: Application Of Oct For Laser Welding Processesmentioning

confidence: 99%

OCT for Efficient High Quality Laser Welding

Dupriez¹,

Truckenbrodt²

2016

Laser Technik Journal

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High requirements for duration and quality of laser welding are the main topics in the line production nowadays, especially in the automotive industry. With acquisition rates up to 100 kHz and microseconds duration capture times, optical coherence tomography (OCT) is a powerful adaptive tool, with a few microns resolution, for real‐time direct non‐contact investigation of material processing. The measurement system used to acquire the workpiece topography enables high accuracy automatic seam tracking, process monitoring and quality assurance (QA), and these functions are executed simultaneously.

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Real time monitoring of laser beam welding keyhole depth by laser interferometry

Cited by 45 publications

References 21 publications

In situ morphology-based defect detection of selective laser melting through inline coherent imaging

In situ morphology-based defect detection of selective laser melting through inline coherent imaging

Keyhole formation and thermal fluid flow-induced porosity during laser fusion welding in titanium alloys: Experimental and modelling

OCT for Efficient High Quality Laser Welding

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