Metals for High Temperature Applications under Extreme Conditions – Development and Testing

Jürgen Merker; M. Koch

doi:10.4028/www.scientific.net/MSF.783-786.1165

Paper Titles

Evaluation of Tool Performance of Recycle-Type Fe₃Al Based Alloy for Pure Cu
p.1142

Effects of Geometric Constraint on Solidification Microstructural Development of Peritectic TiAl Alloys
p.1147

High Temperature Tensile Behavior of Directionally Solidified MAR-M247 Superalloy
p.1153

Feasibility of Cast and Wrought Co-Al-W-X Gamma-Prime Superalloys
p.1159

Metals for High Temperature Applications under Extreme Conditions – Development and Testing
p.1165

Phase Equilibrium between B2 Aluminide NiAl and Nb-Mo bcc Solid Solution Phase
p.1171

Spark Plasma Heat Treated ZrB₂-SiC and HfB₂-SiC Composites
p.1176

Mechanical Behaviors of Alloy 617 with Varied Strain Rates at High Temperatures
p.1182

Damage and Fracture Mechanism of a Nickel-Based Single Crystal Superalloy during Creep at Moderate Temperature
p.1188

HomeMaterials Science ForumMaterials Science Forum Vols. 783-786Metals for High Temperature Applications under...

Metals for High Temperature Applications under Extreme Conditions – Development and Testing

Abstract:

A lot of technical processes require metallic materials which are able to withstand very high temperatures under extreme conditions. Examples are applications in glass industry, space technology and crystal growing. Application temperatures are in the range from 1100°C to 2300°C. Besides the extremely high temperature the materials are often influenced simultaneously by high mechanical loading and chemical attack. Due to their outstanding chemical stability, corrosion resistance and high mechanical strength the platinum group metals, in particular platinum, rhodium and iridium, are therefore ideal materials for high temperature use under extreme conditions. These metals are widely used in spite of their high prices. High temperature applications require high melting point metals, commonly strengthened by solid solution or oxide dispersion hardening. This paper reports e. g. on the development of oxide dispersion hardened platinum and platinum alloys manufactured by fusion technique. Furthermore the paper presents a comprehensive review of studies on platinum materials which facilitate the design of equipment used for high temperature applications under extreme conditions. Stress-rupture strength and creep behavior have been investigated in a temperature range between 1200°C and 2300°C. The results of the investigations can supply a basis to optimize materials selection for high temperature applications under extreme conditions.

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Materials Science Forum (Volumes 783-786)

Pages:

1165-1170

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.783-786.1165

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Online since:

May 2014

Authors:

Jürgen Merker, M. Koch

Keywords:

Creep Behavior, Internal Oxidation, Oxide Dispersion Strengthening, Platinum Alloys, Platinum Group Metals, Solid Solution Strengthening, Stress-Rupture Strength

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