The Effect of Tool Edge Geometry on Tool Performance and Surface Integrity in Turning Ti-6Al-4V Alloys

Burhanuddin, Yanuar; Haron, Che Hassan Che; Ghani, Jaharah A.

doi:10.4028/www.scientific.net/amr.264-265.1211

Cited by 12 publications

(6 citation statements)

References 25 publications

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“…It is generally assumed that an increase in cutting speed leads to a finer surface quality. However, investigations show that the effects are strongly materialdependent and can show opposite tendencies [27,28]. The material-specific differences can be attributed to the material separation mechanisms and side effects, such as adhesions at the cutting edge [29].…”

Section: Turning and Deep Rollingmentioning

confidence: 99%

Investigation of the influence of the forming process and finishing processes on the properties of the surface and subsurface of hybrid components

Budde

Prasanthan

Kruse

et al. 2021

Int J Adv Manuf Technol

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Due to the increased integration of functions, many components have to meet high and sometimes contradictory requirements. One way to solve this problem is Tailored Forming. Here, hybrid semi-finished products are manufactured by a joining or cladding process, which are then hot-formed and finished. For the design of hybrid components for a possible later industrial application, knowledge about properties of hybrid components is required. In this paper it is investigated how the respective process steps of the Tailored Forming process chain change the surface and subsurface properties of the applied cladding layer. For this purpose, shafts made of unalloyed steel are provided with a high-alloy austenitic steel X2CrNiMo19-12 cladding by laser hot-wire cladding. Subsequently, hot forming is carried out by cross-wedge rolling and the finishing by turning and deep rolling. After each process step, the subsurface properties of the cladding such as microstructure, hardness and residual stress state are examined. Thus, the influence of different process steps on the subsurface properties in the process chain of manufacturing hybrid shafts can be analyzed. This knowledge is necessary for the specific adjustment of defined properties for a required application behavior.

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Section: Turning and Deep Rollingmentioning

confidence: 99%

Investigation of the influence of the forming process and finishing processes on the properties of the surface and subsurface of hybrid components

Budde

Prasanthan

Kruse

et al. 2021

Int J Adv Manuf Technol

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“…The magnitude of the influence of the cutting edge radius decreases with increasing hardness of the material being processed. It is possible to say that a smaller radius of rounding of the cutting edge means less roughness of the surface [17][18][19]. The residual stresses also behave on the same principle.…”

Section: Introductionmentioning

confidence: 99%

Influence of selected parameters of drag finishing on tool microgeometry

Pätoprstý,

Buranský,

Jurina

2024

J. Phys.: Conf. Ser.

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The aim of the experiment described in the paper was to determine how selected parameters of drag finishing such as process time, immersion depth and rotation frequency affect microgeometry of cutting edge. Four flute cemented carbide mills with diameter of 10 mm were used in this experiment. These mills were drag finished on prototype drag finishing machine developed on Faculty of Materials Science and Technology, Slovak University of Technology. Alicona Infinte Focus SL measuring machine was used to measure microgeometry of these mills. The main parameter of microgeometry of cutting edge was the size of the radius of cutting edge. In the article we compared which parameter has the biggest influence on size of cutting edge radius and also there was statistical evaluation carried out. The most significant parameter of drag finishing was determined to be the immersion depth.

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“…The surface roughness is significantly influenced by the feed rate during turning. In addition, cutting speed and tool microgeometry also determine the final roughness of a component [30,31]. The mechanical and thermal effects during chip formation are the main factors influencing the subsurface condition.…”

Section: Introductionmentioning

confidence: 99%

“…This generally leads to compressive residual stresses below the surface. On the other hand, large cutting-edge radii lead to greater temperature development, which promotes the formation of tensile residual stresses [30,31]. The influence of process parameters and tool microgeometry on the surface and subsurface properties of hybrid components and their influence on the operating behavior is currently inadequately investigated.…”

Section: Introductionmentioning

confidence: 99%

Production-Related Surface and Subsurface Properties and Fatigue Life of Hybrid Roller Bearing Components

Breidenstein

Denkena

Krödel

et al. 2020

Metals

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By combining different materials, for example, high-strength steel and unalloyed structural steel, hybrid components with specifically adapted properties to a certain application can be realized. The mechanical processing, required for production, influences the subsurface properties, which have a deep impact on the lifespan of solid components. However, the influence of machining-induced subsurface properties on the operating behavior of hybrid components with a material transition in axial direction has not been investigated. Therefore, friction-welded hybrid shafts were machined with different process parameters for hard-turning and subsequent deep rolling. After machining, subsurface properties such as residual stresses, microstructures, and hardness of the machined components were analyzed. Significant influencing parameters on surface and subsurface properties identified in analogy experiments are the cutting-edge microgeometry, S¯, and the feed, f, during turning. The deep-rolling overlap, u, hardly changes the residual stress depth profile, but it influences the surface roughness strongly. Experimental tests to determine fatigue life under combined rolling and rotating bending stress were carried out. Residual stresses of up to −1000 MPa, at a depth of 200 µm, increased the durability regarding rolling-contact fatigue by 22%, compared to the hard-turned samples. The material transition was not critical for failure.

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The Effect of Tool Edge Geometry on Tool Performance and Surface Integrity in Turning Ti-6Al-4V Alloys

Cited by 12 publications

References 25 publications

Investigation of the influence of the forming process and finishing processes on the properties of the surface and subsurface of hybrid components

Investigation of the influence of the forming process and finishing processes on the properties of the surface and subsurface of hybrid components

Influence of selected parameters of drag finishing on tool microgeometry

Production-Related Surface and Subsurface Properties and Fatigue Life of Hybrid Roller Bearing Components

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