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1. Towards the additive manufacturing of Ni-Mn-Ga complex devices with magnetic field induced strain

Author

Mika Salmi, Iñigo Flores Ituarte, Venkata Karthik Nadimpalli, Simo-Pekka Hannula, Frans Nilsén, Joonas Lehtonen, Tampere University, Mechanical Engineering and Metals Industry Standardization in Finland, Technical University of Denmark, Department of Mechanical Engineering, Department of Chemistry and Materials Science, Aalto-yliopisto, Aalto University, and Automation Technology and Mechanical Engineering

Subjects

Materials science, Additive manufacturing, Biomedical Engineering, Mesoscale meteorology, Smart materials, 4D printing, Magnetic shape-memory alloys, Industrial and Manufacturing Engineering, 214 Mechanical engineering, Magnetization, Martensite, General Materials Science, Grain boundary, Crystallite, MFIS, Composite material, Porosity, Engineering (miscellaneous), Microscale chemistry, Tensile testing

Abstract

Funding Information: We gratefully acknowledge the support of the Aalto University seed funding for the DEMINFUN-project ( 974110 ). Frans Nilsén also acknowledges (in part) support by Operational Program Research, Development and Education financed by European Structural and Investment Funds and the Czech Ministry of Education, Youth and Sports (Project No. SOLID21 - CZ.02.1.01/0.0/0.0/16_019/0000760 ). Publisher Copyright: © 2021 The Authors Laser powder bed fusion (L-PBF) is used to produce foam-like Ni-Mn-Ga with tailored microscale and mesoscale features. Ni50-Mn28.2-Ga21.8 (at%) powder was gas atomised and processed in an L-PBF system with a range of energy density from 26.24 and 44.90 J/mm3. We characterised microscale and mesoscale properties, such as the chemical composition, crystal structure, magnetisation measurements, density, and porosity measurements as a function of process parameters, in a systematic design of experiment. Preliminary research on macroscale properties included tensile testing and magnetic field induced strain (MFIS) measurements. Results show how controlling process parameters allows tailoring the Ni-Mn-Ga polycrystalline microstructure. Hence, obtaining twinned martensitic structures with a predominant orientation going across the visible grain boundaries. All the processed samples showed a 56 Am2/kg magnetisation level, close to Ni-Mn-Ga 10 M single crystals. Mesoscale results show a distinctive porosity pattern that is tailored by the process parameters and the laser scanning strategy. In contrast, macroscale mechanical tensile test results show a brittle fracture of Ni-Mn-Ga due to the high porosity with yield stress 2–3 times higher than shown in single crystals. In sum, we built geometrically complex demonstrators with (i) microscale twinned martensitic structures with a predominant orientation going across the visible grain boundaries and (ii) mesoscale tailored periodic porosity patterns created by modifying power, scanning speed, and scanning strategy systematically. L-PBF demonstrates great potential to produce foam-like polycrystalline Ni-Mn-Ga, reducing grain boundary constraints and thus the magnetic force needed for MFIS.

Published

2022