Development of Diffusion Welding Process for High Temperature Materials

Ho Sung Lee; Kyung Ju Min

doi:10.4028/www.scientific.net/KEM.689.3

Paper Titles

Development of Diffusion Welding Process for High Temperature Materials
p.3

Application of Taguchi Technique to Surface-Grinding of Mold Steel
p.7

Effect of Copper Addition to Aluminum on its Metallurgical, Mechanical Characteristics and Surface Roughness after Rolling
p.12

Comparison between Addition of Titanium and Titanium Plus Boron to MgAZ31 on its Grain Size and its Mechanical Characteristics
p.17

Comparison between Mo Addition to Al Grain Refined by Ti and Ti+B on its Metallurgical and Mechanical Characteristics in the Cast and after ECAP Process Conditions
p.23

Damages Caused by Projectile Impact
p.29

Influence of Irradiation Conditions on the Properties of PTFE Micropowder
p.37

The Aligned Carbon Microcoils Having the Straight Type Overall Geometry
p.43

HomeKey Engineering MaterialsKey Engineering Materials Vol. 689Development of Diffusion Welding Process for High...

Development of Diffusion Welding Process for High Temperature Materials

Abstract:

Aerospace vehicle requires structures to withstand intense aerodynamic heating and propulsion system to provide very high effective heat exchange. In order to satisfy both requirements of effective thermal exchange and mechanical properties, high temperature materials, or sometimes dissimilar metals with different properties must be joined together. In this study, it is demonstrated that diffusion welding process can be applied to manufacturing lightweight integral structures of aerospace structural parts with titanium and stainless steel. The results show that the technology to design and develop the diffusion welding process of high temperature metals can be applied for manufacturing of aerospace components for high temperature application.

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Key Engineering Materials (Volume 689)

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3-6

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https://doi.org/10.4028/www.scientific.net/KEM.689.3

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Online since:

April 2016

Authors:

Ho Sung Lee*, Kyung Ju Min

Keywords:

Aerospace, Diffusion Welding, Duplex Steel, Titanium

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