Production of high strength hollow shafts using tool hardening and Q-P process

Production of high strength hollow shafts using tool hardening and Q-P process

Innovation opens new opportunities in the field of processing hollow semi-products, as it offers the potential for manufacturing complex-shaped structural parts with enhanced properties. This introduces a manufacturing route comprising the following steps: internal high pressure forming, hot stampin...

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Main Authors: Masek Bohuslav, Vorel Ivan, Opatová Kateřina, Kurka Petr, Hahn Frank, Mahn Uwe
Format: Article
Language:English
Published: EDP Sciences 2015-01-01
Series:MATEC Web of Conferences
Online Access:http://dx.doi.org/10.1051/matecconf/20152106009
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spelling doaj-48820a4d1cdc4e0c8621ec86022ee0e52021-02-02T01:42:40ZengEDP SciencesMATEC Web of Conferences2261-236X2015-01-01210600910.1051/matecconf/20152106009matecconf-icnft2015_06009Production of high strength hollow shafts using tool hardening and Q-P processMasek Bohuslav0Vorel Ivan1Opatová Kateřina2Kurka Petr3Hahn Frank4Mahn Uwe5Research Centre of Forming Technology – FORTECH, University of West BohemiaResearch Centre of Forming Technology – FORTECH, University of West BohemiaResearch Centre of Forming Technology – FORTECH, University of West BohemiaFraunhofer Institute for Machine Tools and Forming Technology IWUFaculty of Mechanical Engineering, University of Applied SciencesFaculty of Mechanical Engineering, University of Applied SciencesInnovation opens new opportunities in the field of processing hollow semi-products, as it offers the potential for manufacturing complex-shaped structural parts with enhanced properties. This introduces a manufacturing route comprising the following steps: internal high pressure forming, hot stamping and thermomechanical Q&P processing. In this manufacturing route, the demonstration product, a tube–shaped stock, is first austenitized. It is then expanded in a closed die by internal pressure of nitrogen until the material touches the die wall. As a result, it cools down quickly and martensite begins to form. At a temperature above the Mf, the cooling is interrupted and the workpiece is transferred to a furnace and tempered. The furnace temperature is below the Ms temperature. Within several minutes, a mixed microstructure forms, consisting of martensite and stabilized retained austenite. Thanks to this microstructure, the material exhibits a favourable combination of high strength and adequate ductility. Martensite imparts sufficient strength to the material whereas the retained austenite provides ductility. At a carbon level of approximately 0.4 % and with a simple Si-Mn-Cr-based chemistry, strengths of 2000 MPa and A5 mm elongations of 15% can be achieved.http://dx.doi.org/10.1051/matecconf/20152106009
collection DOAJ
language English
format Article
sources DOAJ
author Masek Bohuslav
Vorel Ivan
Opatová Kateřina
Kurka Petr
Hahn Frank
Mahn Uwe
spellingShingle Masek Bohuslav
Vorel Ivan
Opatová Kateřina
Kurka Petr
Hahn Frank
Mahn Uwe
Production of high strength hollow shafts using tool hardening and Q-P process
MATEC Web of Conferences
author_facet Masek Bohuslav
Vorel Ivan
Opatová Kateřina
Kurka Petr
Hahn Frank
Mahn Uwe
author_sort Masek Bohuslav
title Production of high strength hollow shafts using tool hardening and Q-P process
title_short Production of high strength hollow shafts using tool hardening and Q-P process
title_full Production of high strength hollow shafts using tool hardening and Q-P process
title_fullStr Production of high strength hollow shafts using tool hardening and Q-P process
title_full_unstemmed Production of high strength hollow shafts using tool hardening and Q-P process
title_sort production of high strength hollow shafts using tool hardening and q-p process
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2015-01-01
description Innovation opens new opportunities in the field of processing hollow semi-products, as it offers the potential for manufacturing complex-shaped structural parts with enhanced properties. This introduces a manufacturing route comprising the following steps: internal high pressure forming, hot stamping and thermomechanical Q&P processing. In this manufacturing route, the demonstration product, a tube–shaped stock, is first austenitized. It is then expanded in a closed die by internal pressure of nitrogen until the material touches the die wall. As a result, it cools down quickly and martensite begins to form. At a temperature above the Mf, the cooling is interrupted and the workpiece is transferred to a furnace and tempered. The furnace temperature is below the Ms temperature. Within several minutes, a mixed microstructure forms, consisting of martensite and stabilized retained austenite. Thanks to this microstructure, the material exhibits a favourable combination of high strength and adequate ductility. Martensite imparts sufficient strength to the material whereas the retained austenite provides ductility. At a carbon level of approximately 0.4 % and with a simple Si-Mn-Cr-based chemistry, strengths of 2000 MPa and A5 mm elongations of 15% can be achieved.
url http://dx.doi.org/10.1051/matecconf/20152106009
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AT vorelivan productionofhighstrengthhollowshaftsusingtoolhardeningandqpprocess
AT opatovakaterina productionofhighstrengthhollowshaftsusingtoolhardeningandqpprocess
AT kurkapetr productionofhighstrengthhollowshaftsusingtoolhardeningandqpprocess
AT hahnfrank productionofhighstrengthhollowshaftsusingtoolhardeningandqpprocess
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