Development of high performance aluminium alloys tailored for powder bed fusion-laser beam
Doktorsavhandling, 2023

The powder bed fusion-laser beam (PBF-LB) process has lately been regarded as a top choice for creating complicated structures which are not possible via conventional manufacturing. Nevertheless, the pace of alloys for PBF-LB has been slower. Commercially available alloys are derived from cast/ wrought counterparts with limited knowledge of their suitability to PBF-LB. To fully exploit the inherent advantages of PBF-LB process, there is thus a growing need to develop alloy compositions with help from computational tools. This research work focused on the development of aluminium alloy systems tailored for the PBF-LB process. Leveraging the possibilities and limitations of PBF-LB process and with the help of CALPHAD tools, two types of alloying approaches were investigated namely in-situ alloying and ex-situ mixing. The key alloy design objectives were to avoid solidification cracking while attaining higher solid solubilities combined with a refined microstructure. The mechanical property objective was >450 MPa strength and high-temperature strength up to 573 K combined with general corrosion resistance.
Al-Mn-Cr-Zr based alloy system resulting from this thesis study include several variants with different amounts of alloying elements. Gas-atomised powder was used, and fully dense samples were processed using optimised PBF-LB process. This was followed by post-processing heat treatments to optimise mechanical properties. This created an alloy system with mechanical properties including yield strengths 250-500 MPa, elongation to failure 5-25% and bending fatigue 140-200 MPa. In as-printed state, strengthening was caused by a combination of solid solution strengthening and grain size effect. The strengthening from precipitates was observed after direct ageing heat treatments. The microstructure was characterised by SEM, TEM and in-situ synchrotron measurements. Long-term isothermal testing at 623 K for >1000 h showed a superior performance (-17 HV or 12% drop). High-temperature tensile testing at 573 K showed yield strengths >150 MPa, surpassing most commercially available Al-alloys.
These novel high performance alloys expand the available material performance envelope and create an edge over currently available systems while completely avoiding critical or rare earth elements. Such tailored alloy systems are shown to better utilise PBF-LB processing conditions to enhance material properties thus increasing the potential applications.

Precipitation kinetics

Powder bed fusion-laser beam

Aluminium alloys

Integrated computational materials engineering

Additive manufacturing

Alloy design

Heat treatments

Virtual Development Laboratory (VDL), Chalmers Tvärgata 4C, Chalmers University of Technology, Gothenburg
Opponent: Prof. Dr. Eric Jägle, Universität der Bundeswehr, Munich, Germany

Författare

Bharat Mehta

Chalmers, Industri- och materialvetenskap, Material och tillverkning

Advancing novel Al-Mn-Cr-Zr based family of alloys tailored for powder bed fusion-laser beam process

Journal of Alloys and Compounds,;Vol. 967(2023)

Artikel i vetenskaplig tidskrift

In-situ observation of precipitate formation using scanning X-ray fluorescence in novel Al-alloy tailored for additive manufacturing; I.Lazar, B.Mehta, V.Bertschová, S.B.A.Malladi, R. Zhe Tu, S.Das, J.Hagemann, G.Falkenberg, K.Frisk, A.Mikkelsen, L.Nyborg

Role of Cr in Mn-rich precipitates for Al-Mn-Cr-Zr family of alloys tailored for additive manufacturing; B.Mehta, K.Frisk, R.Naraghi, L.Nyborg

Mechanical properties of Al-Mn-Cr-Zr based alloys tailored for powder bed fusion-laser beam; B.Mehta, S.Bengtsson, D.Riabov, E.Natesan, K.Frisk, J.Ahlström, L.Nyborg

Future of aluminium alloys tailored for additive manufacturing

Additive manufacturing (AM), also referred to as 3D printing has become lucrative over the past decade by designers, engineers, artists all around the world. The benefit of designing novel structures via AM has led to fascinating products in biomedical and aerospace sectors. Together with design benefits, reduced waste, time savings to production and individual parts for free makes AM competitive. However, factors limiting its use are higher cost, fewer materials available and lower time to manufacture large scale components. This thesis work has successfully tried to showcase an entirely novel material which is an Al-alloy family tailored for powder bed fusion-laser beam (PBF-LB) process. PBF-LB is the most common AM technique. The alloy design was aimed at producing high strength combined with high temperature strength, to show Al-alloys which could tentatively replace Fe- or Ti- alloys in automotive or aerospace sectors for example. Al-Mn-Cr-Zr based alloy family has successfully been produced using PBF-LB technique to produce dense samples. Microstructural and mechanical property studies showed promising results with high ductility in as-printed condition. Upon direct ageing heat treatment, high strengths could be achieved. The alloys were thoroughly tested for both high temperature properties namely thermal stability tests and high temperature tensile tests. Both the tests proved that these alloys outperform most Al-alloys available thus pushing the material envelope. Eventually, two demonstrators were produced in form of a manifold used in aircraft landing systems and another as a heat exchanger operating at high temperature

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Vetenskapsrådet (VR) (2020-06159), 2021-01-01 -- 2024-12-31.

Lättare komponenter genom additiv tillverkning av aluminiumlegeringar

VINNOVA (2018-02844), 2018-10-15 -- 2021-10-31.

Ämneskategorier

Materialteknik

Bearbetnings-, yt- och fogningsteknik

Metallurgi och metalliska material

Styrkeområden

Produktion

ISBN

978-91-7905-909-5

Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5375

Utgivare

Chalmers

Virtual Development Laboratory (VDL), Chalmers Tvärgata 4C, Chalmers University of Technology, Gothenburg

Online

Opponent: Prof. Dr. Eric Jägle, Universität der Bundeswehr, Munich, Germany

Mer information

Senast uppdaterat

2023-08-25