EFFECT MECHANISM OF Mn CONTENTS ON SHAPE MEMORY OF Fe-Mn-Si-Cr-Ni ALLOYS

doi:10.11900/0412.1961.2014.00394

Acta Metall Sin

2015, Vol. 51

Issue (2): 201-208 DOI: 10.11900/0412.1961.2014.00394

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EFFECT MECHANISM OF Mn CONTENTS ON SHAPE MEMORY OF Fe-Mn-Si-Cr-Ni ALLOYS

ZHANG Chengyan¹, SONG Fan¹, WANG Shanling², PENG Huabei¹, WEN Yuhua¹(

)

1 College of Manufacturing Science and Engineering, Sichuan University, Chengdu 610065
2 Analytical and Testing Center, Sichuan University, Chengdu 610065

Cite this article:

ZHANG Chengyan, SONG Fan, WANG Shanling, PENG Huabei, WEN Yuhua. EFFECT MECHANISM OF Mn CONTENTS ON SHAPE MEMORY OF Fe-Mn-Si-Cr-Ni ALLOYS. Acta Metall Sin, 2015, 51(2): 201-208.

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Abstract

Fe-Mn-Si base shape memory alloys (SMAs), as compared with Ni-Ti and Cu base SMAs, have attracted much attention since the 1980s due to their promising advantages, such as low cost, good workability and weldability. However, the recovery strain of polycrystalline Fe-Mn-Si base SMAs is only about 2%~3% except single crystals and ribbons ones. At the present time, in order to enhance the recovery strain of this kind of alloys, some methods such as thermo-mechanical training, ausforming and thermo-mechanical treatment are used. In recent years, the research group had prepared training-free cast Fe-Mn-Si base alloys showing an excellent shape memory effect (SME). Unfortunately, the grains of cast Fe-Mn-Si base alloys are coarse, certainly leading to low yield strength and recovery stress. Many factors affecting the shape memory effect, such as alloy elements, the amount of pre-strain, deformation temperatures, annealing treatments and the training, have been studied. However, there is a debate on the effect of Mn contents on the shape memory effect of Fe-Mn-Si base alloys. The aim of this work is to clarify the debate, shape memory effect and microstructures of solution treated Fe-(14~21)Mn-5.5Si-8.5Cr-5Ni alloys were investigated by OM, EBSD, XRD, TEM and SQUID before and after deformation at 10 K higher than their start temperature of martensitic transformation (M_s+10 K). The result showed that the shape memory effect of solution treated Fe-(14~21)Mn-5.5Si-8.5Cr-5Ni alloys increased with the Mn contents. There are two reasons for this result. One is that the difference value between austenitic yield strength and critical stress of stress-induced e martensite increased with the Mn contents. In other word, the ability resisting plastic deformation was improved by increasing the Mn contents. The other is that the reversibility of e martensite reverse transformation was enhanced by increasing the Mn contents because the width of stress-induced e martensite decreased while the α' martensite was difficult to be introduced with increasing the Mn contents。

Key words: shape memory alloy Mn stress-induced e martensite slip

Received: 17 July 2014

ZTFLH:

TG139.6

Fund: Supported by National Natural Science Foundation of China (Nos.51171123 and 51271128)

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	Chengyan ZHANG
	Fan SONG
	Shanling WANG
	Huabei PENG
	Yuhua WEN

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https://www.ams.org.cn/EN/10.11900/0412.1961.2014.00394 OR https://www.ams.org.cn/EN/Y2015/V51/I2/201

Table 1 Chemical compositions of Fe-Mn-Si-Cr-Ni alloys and phase transformation temperatures of solution treated alloys

Fig.1 Effect of deformation strains on the recovery strain of solution treated 14Mn, 18Mn and 21Mn alloys deformed at their M_s+10 K

Fig.2 Color OM images of solution treated 14Mn (a), 18Mn (b) and 21Mn (c) alloys

Fig.3 Color OM images of solution treated 14Mn (a, d, g), 18Mn (b, e, h) and 21Mn (c, f, i) alloys subjected to deformation strains of 4% (a~c), 7% (d~f) and 9% (g~i) at their M_s+10 K

Fig.4 XRD spectra of solution treated 14Mn (a), 18Mn (b) and 21Mn (c) alloys subjected to different deformation strains at their M_s+10 K and volume fraction of stress-induced e martensite (d)

Fig.5 Saturation magnetizations of solution treated 14Mn, 18Mn and 21Mn alloys subjected to different deformation strains at their M_s+10 K

Fig.6 TEM image (a) and SAED pattern of circle in Fig.6a (b) of 21Mn alloy subjected to 9% deformation at its M_s+10 K (The subscripts T and e represent hcp twin and stress-induced e martensite, respectively)

Fig.7 Cumulative frequency distributing graphs of stress-induced e martensite width for solution treated 14Mn, 18Mn and 21Mn alloys subjected to deformation strains of 4% (a), 7% (b) and 9% (c) at their M_s+10 K

Table 2 Average width of stress-induced e martensite for solution treated 14Mn, 18Mn and 21Mn alloys subjected to different deformation strains at their M_s+10 K

Fig 8 Relationships between 0.2% proof stress s_0.2 and deformation temperatures of solution treated 14Mn (a), 18Mn (b) and 21Mn (c) alloys ( represents the highest temperature of stress-induced e martensite transformation)

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