Tool surface with a supporting plateau of hard particles for deep drawing of high alloy steel

Freiße, Hannes; Seefeld, Thomas

doi:10.1051/matecconf/201819014006

Cited by 3 publications

(2 citation statements)

References 15 publications

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“…Moreover, the surface roughness of the metal sheet was increasing because the hard particles were penetrating the surface. These results were also observed for deep drawing of cups with MMC tools [8]. The formed cups showed scores due to the higher contact pressures in the radius area of the tool.…”

Section: Introductionsupporting

confidence: 63%

Agglomerated Tungsten Carbide: A New Approach for Tool Surface Reinforcement

Ditsche

Seefeld

2019

KEM

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For the first time tungsten carbide particles were deliberately agglomerated by two-step laser melt injection. After a regular laser melt injection, a second laser melt injection was performed with additional tungsten carbide particles in order to generate a large local agglomerate. The influence of laser power, laser spot diameter, powder feeding rate and pulse time on the agglomeration process was examined and depended on the energy input and tungsten carbide quantity introduced into the metal matrix composite surface. Chemical composition of the agglomerates corresponded with the values of tungsten carbide and the agglomerate hardness was slightly lower. It is intended to apply this agglomerated tungsten carbide for deep drawing tools under Dry Metal Forming conditions.

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Section: Introductionsupporting

confidence: 63%

Agglomerated Tungsten Carbide: A New Approach for Tool Surface Reinforcement

Ditsche

Seefeld

2019

KEM

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“…LMI with fused tungsten carbide (FTC) particles in the copper alloy Hovadur® CNCS led to a significant improvement in wear resistance against the hardened and gas nitrided steel 1.2343 [2]. Tribological tests for an aluminum bronze and FTC MMC have shown that wear can be reduced by 76% [3]. The service life of these MMC surfaces with ceramic particles are dependent on the residual stress state [4].…”

Section: Introductionmentioning

confidence: 99%

Temperature and distortion in laser melt injection of MMC wear-resistant coatings in a copper beryllium alloy

Bohlen,

Langebeck,

Seefeld

2023

IOP Conf. Ser.: Mater. Sci. Eng.

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Wear-resistant coatings made of MMC materials (metal matrix composites) are ideal for increasing the service life of tools subjected to high abrasive stresses. Such MMC surfaces can be produced by laser melt injection during the manufacturing process of the tools or subsequently as a retrofit near-net-shape. However, during laser melt injection (LMI) thermally induced residual stresses can be introduced into the MMC surfaces. These can have a detrimental effect on the service life of these surfaces and thus reduce the positive effect of wear resistance. In order to determine the influence hard particles injected during LMI have on residual stresses within the surface layer the distortion of the surface layer was evaluated. MMC layers consisting of a copper beryllium matrix and fused tungsten carbide hard particles were created by LMI. The MMC layers are compared to parts with remelted surfaces. Laser power and process velocity were varied to examine their influence on distortion. The process temperature was recorded on the melt pool by a two-color pyrometer. After the process the top layer of the MMC surface was cut off by wire EDM and then measured with a coordinate measuring machine. It is shown that an increase of incorporated powder mass per unit length and process temperature lead to higher distortions.

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Local Laser Particle Fusion: Fusing of Hard Particles for the Reduction of High Contact Pressures in MMC Tool Surfaces

Ditsche

Seefeld

2020

JOM

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Tool surface with a supporting plateau of hard particles for deep drawing of high alloy steel

Cited by 3 publications

References 15 publications

Agglomerated Tungsten Carbide: A New Approach for Tool Surface Reinforcement

Agglomerated Tungsten Carbide: A New Approach for Tool Surface Reinforcement

Temperature and distortion in laser melt injection of MMC wear-resistant coatings in a copper beryllium alloy

Local Laser Particle Fusion: Fusing of Hard Particles for the Reduction of High Contact Pressures in MMC Tool Surfaces

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