Key criterion for achieving giant recovery strains in polycrystalline Fe-Mn-Si based shape memory alloys

Peng, Huabei; Wang, Gaixia; Wang, Shanling; Chen, Jie; MacLaren, Ian; Wen, Yuhua

doi:10.1016/j.msea.2017.11.071

Cited by 49 publications

(12 citation statements)

References 107 publications

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“…Fe-SMAs have attracted a considerable attention as a cost-effective alternative to the NiTi alloys over the past two decades [11][12][13]23] Fe-SMAs exhibit high stiffness and yield strength and high recovery stress [24] and induce a strong SME. [25] It has been known that the SME of the Fe-SMAs can be further enhanced when fine precipitations such as NbC or VC are distributed in the microstructures. [12,13] Very recently, we successfully fabricated a Fe-17Mn-5Si-10Cr-4Ni (wt.%) alloy via L-PBF for the first time, which showed a strong SME and high mechanical strength even though the alloy did not contain any carbide forming element for enhancing the SME by the fine precipitations.…”

Section: Introductionmentioning

confidence: 99%

3D and 4D Printing of Complex Structures of FeMnSi‐Based Shape Memory Alloy Using Laser Powder Bed Fusion

Kim

Ferretto

Leinenbach

et al. 2022

Adv Materials Inter

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Section: Introductionmentioning

confidence: 99%

3D and 4D Printing of Complex Structures of FeMnSi‐Based Shape Memory Alloy Using Laser Powder Bed Fusion

Kim

Ferretto

Leinenbach

et al. 2022

Adv Materials Inter

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“…It was pointed out that the alloy can be hot rolled with total reduction degrees up to 80 %, without cracking, which enabled an ultimate strain up to 72 %, during tensile failure tests [1]. Thus, FeMnSiCrNi SMAs have been recognized as corrosion resistant, with the capacity to accommodate high recovery strains, reaching 7.7 % in the case of an as-cast Fe-19Mn-5.5Si-9Cr-4.5Ni alloy with an average grain size above 0.6 mm [3]. Based on these characteristics, practical applications were devised.…”

Section: Introductionmentioning

confidence: 99%

Structural Changes in a Powder Metallurgy 66fe-14mn-6si-9cr-5ni (Mass. %) Shape Memory Alloy Subjected to Bending Creep

Ciurcă¹,

Pricop²,

Agop³

et al. 2022

IJMMT

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Fe-14Mn-6Si-9Cr-5Ni (mass. %) shape memory alloy (SMA) has been developed as a commercial grade of Fe-Mn-Si based SMAs with excellent formability and corrosion resistance. Producing FeMnSiCrNi SMAs by powder metallurgy enables a better control of chemical composition and grain size. This paper discusses the variation of bending creep deformation, as a function of time, temperature and force, in the case of a powder metallurgy (PM) Fe-14Mn-6Si-9Cr-5Ni SMA with 50 % mechanically alloyed powder volume. Creep test temperatures were selected based on phase transitions determined by dynamic mechanical analysis (DMA), during heating. The results suggested the tendency of martensite plate variants to reorient along a common direction, after creep.

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“…The development of Fe-Mn-Si based SMAs led to Fe-Mn-Si-Cr (1990) [10] and Fe-Mn-Si-Cr-Ni (1991) [11]. Fe-Mn-Si-Cr-Ni SMAs are corrosion resistant and they are able to recover strains as large as 7.7 % [12].…”

Section: Introductionmentioning

confidence: 99%

On the Free Recovery Bending Shape Memory Effect in Powder Metallurgy FeMnSiCrNi

et al. 2021

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This paper presents the results of an original experimental study on the training capacity of a powder metallurgy (PM) FeMnSiCrNi shape memory alloy (SMA). The specimens were sintered under protective atmosphere from blended elemental powders, 50 vol.%. of alloy particles being mechanically alloyed. Lamellar specimens, hot rolled to 1 mm thickness, were bent against cylindrical calibres with five decreasing radii, to induce cold shapes with higher and higher deformation degree, as compared to the straight hot shape. During the training procedure, bent specimens were heated with a hot air gun, and developed free-recovery shape memory effect (SME) and partially deflected, by reducing their curvature. The first set of experiments involved fastening the specimens at one end, heating it and monitoring free end’s displacement by means of cinematographic analysis. Within the second set of experiments, both cold and hot shapes were recorded and digitalized and their chord’s length (b) and circle segment height (a) were measured and the radius was determined as R = a/2 + b2/8a for the cold (Rc) and hot shapes (Rh). Finally, the shape recovery degree was calculated for the nth calibre as Δrecn = (Rhn-Rrn)/(Rhn-1-Rrn) and the variation of Δrecn with calibre’s radius was discussed.

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Key criterion for achieving giant recovery strains in polycrystalline Fe-Mn-Si based shape memory alloys

Cited by 49 publications

References 107 publications

3D and 4D Printing of Complex Structures of FeMnSi‐Based Shape Memory Alloy Using Laser Powder Bed Fusion

3D and 4D Printing of Complex Structures of FeMnSi‐Based Shape Memory Alloy Using Laser Powder Bed Fusion

Structural Changes in a Powder Metallurgy 66fe-14mn-6si-9cr-5ni (Mass. %) Shape Memory Alloy Subjected to Bending Creep

On the Free Recovery Bending Shape Memory Effect in Powder Metallurgy FeMnSiCrNi

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