Thermal and Microstructure Study of the Chip Formation During Turning of Ti64 β Lamellar Titanium Structure

Wagner, Vincent; Barelli, Floran; Dessein, Gilles; Laheurte, Raynald; Darnis, Phillipe; Cahuc, Olivier; Mousseigne, Michel

doi:10.1115/1.4038597

Cited by 9 publications

(5 citation statements)

References 26 publications

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“…This initial study thus shows the randomness of chip formation. A study from [10] concerning the influence of cutting conditions on chip formation then shows that adiabatic shear and cracking become regular when the feed rate and therefore the shear forces are high enough to generate them despite the orientation of the colonies. The objective of the next part is then to observe the effect of this particular chip formation on the chip flow length.…”

Section: Chip Formationmentioning

confidence: 99%

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Evolution of contact lengths during the turning of treated Ti64 β

Wagner

2023

Materials Research Proceedings

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Abstract. One of the main ways to increase productivity during the machining of titanium alloy parts is to control the wear mechanisms and consequently the life of the cutting tools. The state-of-the-art shows wear phenomena generated mainly by diffusion. The latter is due to the intrinsic physical properties of titanium generating high temperatures on the cutting and relief faces. Concerning the secondary cutting zone, the wear phenomena result from thermomechanical actions induced by the contact between the secondary zone of the chip and the cutting face of the tool. The analysis of the contact lengths, divided into two parts (sliding contact and sticking contact), is then a strong indicator to be privileged in order to allow the understanding of the present mechanisms. This analysis is even more important when machining processed Ti64  in which chip formation is no longer periodic but a function of the angle between the primary shear band and the orientation of the individual colonies comprising the titanium. The purpose of this article is the analysis of the contact lengths during the machining of Ti64 treated  . After having presented the experimental device allowing visualising the evolution of the contact length between the chip and the cutting face, a statistical analysis based on the collected images makes it possible to put forward the differences of sliding behaviour on the cutting face. It appears that the distribution of the collected values allows explaining and extrapolating the wear appearing on the cutting face.

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Section: Chip Formationmentioning

confidence: 99%

“…Wagner and al. [10] shows that chip formation during the machining of Ti64 β does not follow the cutting process introduced by [11]. It then appears that chip formation is not constant over time but is a function of the orientation of the structure encountered during the creation of the shear band.…”

Section: Introductionmentioning

confidence: 98%

Evolution of contact lengths during the turning of treated Ti64 β

Wagner

2023

Materials Research Proceedings

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“…Understanding the mechanisms of chip formation under complex thermomechanical loads require developing dedicated experimental set-up. In the cutting zone, the material undergoes high plastic deformation and local temperature rise that may induce changes in the material microstructure [1,2] as well as its mechanical and physical properties. Establishing the link between the thermomechanical load and the material microstructure evolution leads to develop physical-based models [3][4][5][6] that are suitable for numerical simulation of the machining processes.…”

Section: Introductionmentioning

confidence: 99%

Kinematic fields measurement during Ti-6Al-4V chip formation using new high-speed imaging system

Zouabi

Calamaz

Wagner

et al. 2023

Int J Adv Manuf Technol

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In-situ visualization of the material flow during orthogonal cutting is achieved using new high-speed optical system. Difficulties arise from the submillimetric size of the cutting zone. Therefore, a dedicated optical system was designed allowing for local scale analysis of chip formation. The Digital Image Correlation (DIC) technique is applied on recorded images from the cutting zone to measure the kinematic fields. Then, the effect of the cutting conditions on chip formation is presented with local scale analysis.

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“…Understanding the mechanisms of chip formation under complex thermomechanical loads requires developing dedicated experimental set-up. In the cutting zone, the material undergoes high plastic deformation and local temperature rise that may induce changes in the material microstructure Haythem Zouabi haythem.zouabi@u-bordeaux.fr Laboratoire Génie de Production, ENIT-INPT, Université de Toulouse, Toulouse, Tarbes, 65440, France [1,2] as well as its mechanical and physical properties. Establishing the link between the thermomechanical load and the material microstructure evolution leads to develop physical-based models [3][4][5][6] that are suitable for numerical simulation of the machining processes.…”

Section: Introductionmentioning

confidence: 99%

“…2 NSSD: normalized sum of squared differences 3 NSSD: zero normalized sum of squared differences 4 NCC: normalized cross-correlation 5 ZNCC: zero normalized cross-correlation Inc (incremental)…”

mentioning

confidence: 99%