Effect of temperature on mechanical response of austenitic materials

Global increase in energy consumption and global warming require more energy production but less CO2emission. Increase in efficiency of energy production is an effective way for this purpose. This can be reached by increasing boiler temperature and pressure in a biomass power plant. By increasing ma...

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Main Author: Calmunger, Mattias
Format: Others
Language:English
Published: Linköpings universitet, Konstruktionsmaterial 2011
Subjects:
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-73748
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spelling ndltd-UPSALLA1-oai-DiVA.org-liu-737482013-01-08T13:51:16ZEffect of temperature on mechanical response of austenitic materialsengCalmunger, MattiasLinköpings universitet, Konstruktionsmaterial2011Dynamic strain agingbiomass power plantaustenitic stainless steelnickel base alloystacking fault energytwinsGlobal increase in energy consumption and global warming require more energy production but less CO2emission. Increase in efficiency of energy production is an effective way for this purpose. This can be reached by increasing boiler temperature and pressure in a biomass power plant. By increasing material temperature 50°C, the efficiency in biomass power plants can be increased significantly and the CO2emission can be greatly reduced. However, the materials used for future biomass power plants with higher temperature require improved properties. Austenitic stainless steels are used in most biomass power plants. In austenitic stainless steels a phenomenon called dynamic strain aging (DSA), can occur in the operating temperature range for biomass power plants. DSA is an effect of interaction between moving dislocations and solute atoms and occurs during deformation at certain temperatures. An investigation of DSA influences on ductility in austenitic stainless steels and nickel base alloys have been done. Tensile tests at room temperature up to 700°C and scanning electron microscope investigations have been used. Tensile tests revealed that ductility increases with increased temperature for some materials when for others the ductility decreases. This is, probably due to formation of twins. Increased stacking fault energy (SFE) gives increased amount of twins and high nickel content gives a higher SFE. Deformation mechanisms observed in the microstructure are glide bands (or deformations band), twins, dislocation cells and shear bands. Damage due to DSA can probably be related to intersection between glide bands or twins, see figure 6 a). Broken particles and voids are damage mechanisms observed in the microstructure. Student thesisinfo:eu-repo/semantics/bachelorThesistexthttp://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-73748application/pdfinfo:eu-repo/semantics/openAccess
collection NDLTD
language English
format Others
sources NDLTD
topic Dynamic strain aging
biomass power plant
austenitic stainless steel
nickel base alloy
stacking fault energy
twins
spellingShingle Dynamic strain aging
biomass power plant
austenitic stainless steel
nickel base alloy
stacking fault energy
twins
Calmunger, Mattias
Effect of temperature on mechanical response of austenitic materials
description Global increase in energy consumption and global warming require more energy production but less CO2emission. Increase in efficiency of energy production is an effective way for this purpose. This can be reached by increasing boiler temperature and pressure in a biomass power plant. By increasing material temperature 50°C, the efficiency in biomass power plants can be increased significantly and the CO2emission can be greatly reduced. However, the materials used for future biomass power plants with higher temperature require improved properties. Austenitic stainless steels are used in most biomass power plants. In austenitic stainless steels a phenomenon called dynamic strain aging (DSA), can occur in the operating temperature range for biomass power plants. DSA is an effect of interaction between moving dislocations and solute atoms and occurs during deformation at certain temperatures. An investigation of DSA influences on ductility in austenitic stainless steels and nickel base alloys have been done. Tensile tests at room temperature up to 700°C and scanning electron microscope investigations have been used. Tensile tests revealed that ductility increases with increased temperature for some materials when for others the ductility decreases. This is, probably due to formation of twins. Increased stacking fault energy (SFE) gives increased amount of twins and high nickel content gives a higher SFE. Deformation mechanisms observed in the microstructure are glide bands (or deformations band), twins, dislocation cells and shear bands. Damage due to DSA can probably be related to intersection between glide bands or twins, see figure 6 a). Broken particles and voids are damage mechanisms observed in the microstructure.
author Calmunger, Mattias
author_facet Calmunger, Mattias
author_sort Calmunger, Mattias
title Effect of temperature on mechanical response of austenitic materials
title_short Effect of temperature on mechanical response of austenitic materials
title_full Effect of temperature on mechanical response of austenitic materials
title_fullStr Effect of temperature on mechanical response of austenitic materials
title_full_unstemmed Effect of temperature on mechanical response of austenitic materials
title_sort effect of temperature on mechanical response of austenitic materials
publisher Linköpings universitet, Konstruktionsmaterial
publishDate 2011
url http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-73748
work_keys_str_mv AT calmungermattias effectoftemperatureonmechanicalresponseofausteniticmaterials
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