Additively manufactured cellular structures: Impact of microstructure and local strains on the monotonic and cyclic behavior under uniaxial and bending load

In order to meet the demand for optimized light-weight parts, the development of load adapted structures has begun to play a key role in today's research. Promising candidates are complex cellular structures, which can be adapted to the loading conditions by use of Additive Manufacturing techni...

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Veröffentlicht in:	Journal of materials processing technology 2013-09, Vol.213 (9), p.1558-1564
Hauptverfasser:	Brenne, F., Niendorf, T., Maier, H.J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Additive manufacturing (AM) Additives Bending Cellular structure Cellular structures Digital image correlation (DIC) Electron back scatter diffraction Heat treatment Laser beam melting Mechanical properties Microstructure Selective laser melting (SLM)
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container_title	Journal of materials processing technology
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creator	Brenne, F. Niendorf, T. Maier, H.J.
description	In order to meet the demand for optimized light-weight parts, the development of load adapted structures has begun to play a key role in today's research. Promising candidates are complex cellular structures, which can be adapted to the loading conditions by use of Additive Manufacturing techniques. The current study addresses the mechanical behavior of open cellular structures produced by Selective Laser Melting. Samples of Ti–6Al–4V were processed, heat-treated and tested under monotonic and cyclic loading applying both uniaxial and bending loads. To reveal microstructure – mechanical property – relationships an in situ approach using electron back scatter diffraction and digital image correlation was applied. The results clarify the impact of a post-SLM heat treatment on the mechanical performance of cellular structures made from Ti–6Al–4V. Local strains determined by DIC reveal structure weaknesses already at low degrees of deformation and at an early stage of lifetime. The in situ approach helps in understanding the mechanical behavior and allows for local adaptation of the cell design in order to obtain improved load adapted structures.
doi_str_mv	10.1016/j.jmatprotec.2013.03.013
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Promising candidates are complex cellular structures, which can be adapted to the loading conditions by use of Additive Manufacturing techniques. The current study addresses the mechanical behavior of open cellular structures produced by Selective Laser Melting. Samples of Ti–6Al–4V were processed, heat-treated and tested under monotonic and cyclic loading applying both uniaxial and bending loads. To reveal microstructure – mechanical property – relationships an in situ approach using electron back scatter diffraction and digital image correlation was applied. The results clarify the impact of a post-SLM heat treatment on the mechanical performance of cellular structures made from Ti–6Al–4V. Local strains determined by DIC reveal structure weaknesses already at low degrees of deformation and at an early stage of lifetime. 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Promising candidates are complex cellular structures, which can be adapted to the loading conditions by use of Additive Manufacturing techniques. The current study addresses the mechanical behavior of open cellular structures produced by Selective Laser Melting. Samples of Ti–6Al–4V were processed, heat-treated and tested under monotonic and cyclic loading applying both uniaxial and bending loads. To reveal microstructure – mechanical property – relationships an in situ approach using electron back scatter diffraction and digital image correlation was applied. The results clarify the impact of a post-SLM heat treatment on the mechanical performance of cellular structures made from Ti–6Al–4V. Local strains determined by DIC reveal structure weaknesses already at low degrees of deformation and at an early stage of lifetime. 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Promising candidates are complex cellular structures, which can be adapted to the loading conditions by use of Additive Manufacturing techniques. The current study addresses the mechanical behavior of open cellular structures produced by Selective Laser Melting. Samples of Ti–6Al–4V were processed, heat-treated and tested under monotonic and cyclic loading applying both uniaxial and bending loads. To reveal microstructure – mechanical property – relationships an in situ approach using electron back scatter diffraction and digital image correlation was applied. The results clarify the impact of a post-SLM heat treatment on the mechanical performance of cellular structures made from Ti–6Al–4V. Local strains determined by DIC reveal structure weaknesses already at low degrees of deformation and at an early stage of lifetime. 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subjects	Additive manufacturing (AM) Additives Bending Cellular structure Cellular structures Digital image correlation (DIC) Electron back scatter diffraction Heat treatment Laser beam melting Mechanical properties Microstructure Selective laser melting (SLM)
title	Additively manufactured cellular structures: Impact of microstructure and local strains on the monotonic and cyclic behavior under uniaxial and bending load
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