3D Simulation and Process Optimization of Laser Assisted Milling of Ti6Al4V

Zamani, Hassan Adrian; Hermani, Jan-Patrick; Sonderegger, Bernhard; Sommitsch, Christof

doi:10.1016/j.procir.2013.06.068

Cited by 34 publications

(14 citation statements)

References 6 publications

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“…LAM can reduce the cutting feed forces by 22% for ceramics [53] and hardened steels [60]. For titanium alloys, a reduction of force in X-direction up to 25%, Y-direction up to 60% and Z-direction up to 65% can be achieved [68]. In sum of all, LAM can ensure cutting forces reduction by up to 40 % for different materials [54].…”

Section: Cutting Forces and Materials Removal Ratementioning

confidence: 99%

Laser Ablation and Laser-Hybrid Ablation Processes: A Review

Ahmed¹,

Darwish²,

Alahmari³

2015

Materials and Manufacturing Processes

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Laser beam machining (LBM) has proven its applications and advantages over almost all the range of engineering materials. It offers its competences from macro machining to micro and nano-machining of simple-to-complex shapes. The hybrid approaches in laser ablation have demonstrated much improved results in terms of material removal rate, surface integrity, geometrical tolerances, thermal damage, metallurgical alterations and many more. The flipside of LBM is the existence of universal problems associated with its thermal ablation mechanism. In order to alleviate or reduce the inherent problems of LBM, a massive research has been done during the past decade in order to build a relatively new route of laser-hybrid processes. This paper reviews the research work carried out so far in the area of LBM and its hybrid processes for different materials and shapes. The article also highlights the research gaps and future research directions in the context of laser and laser-hybrid ablation.

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Section: Cutting Forces and Materials Removal Ratementioning

confidence: 99%

Laser Ablation and Laser-Hybrid Ablation Processes: A Review

Ahmed¹,

Darwish²,

Alahmari³

2015

Materials and Manufacturing Processes

View full text Add to dashboard Cite

show abstract

“…LAM can reduce the cutting feed forces by 22 % for ceramics [90] and hardened steels [100]. For titanium alloys, a reduction of force in x-direction up to 25 %, y-direction up to 60 % and z-direction up to 65 % can be achieved [101]. In sum of all, LAM can ensure cutting forces reduction by up to 40 % for different materials [91].…”

Section: Cutting Forces and Materials Removal Ratementioning

confidence: 99%

Laser Beam Machining, Laser Beam Hybrid Machining, and Micro-channels Applications and Fabrication Techniques

Darwish

Ahmed

Al‐Ahmari

2016

Advanced Structured Materials

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Laser beam machining (LBM) has proven its applications and advantages over almost all the range of engineering materials. It offers its competences from macro machining to micro and nano-machining of simple-to-complex shapes. The flipside of LBM is the existence of universal problems associated with its thermal ablation mechanism. In order to alleviate or reduce the inherent problems of LBM, a massive research has been done during the past decade and in turn build a relatively new route of laser-hybrid processes. The hybrid approaches in laser ablation have demonstrated much improved results in terms of material removal rate, surface integrity, geometrical tolerances, thermal damage, metallurgical alterations and many more. This chapter reviews the research work carried out so far in the area of LBM and its hybrid processes for different materials and shapes.

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“…Bermingham et al [14] studied laser-assisted milling strategies with different cutting tool paths using a CAM program. Zamani et al [15] studied tool wear and cutting force with the Ti6Al4V alloy with a 3-D FEM analysis. Kumar and Melkote [16] evaluated the process capabilities of laser-assisted micro milling (LAMM) by measuring the cutting force, tool wear and surface roughness.…”

Section: Introductionmentioning

confidence: 99%