Microstructure Control and High Temperature Properties of Al-Mn-Based Alloys

doi:10.11900/0412.1961.2017.00010

Acta Metall Sin

2017, Vol. 53

Issue (11): 1487-1494 DOI: 10.11900/0412.1961.2017.00010

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Microstructure Control and High Temperature Properties of Al-Mn-Based Alloys

Xiancui LIU, Ye PAN(

), Zhijiao TANG, Weiqiao HE, Tao LU

Jiangsu Key Laboratory for Advanced Metallic Materials, School of Materials Science and Engineering, Southeast University, Nanjing 211189, China

Cite this article:

Xiancui LIU, Ye PAN, Zhijiao TANG, Weiqiao HE, Tao LU. Microstructure Control and High Temperature Properties of Al-Mn-Based Alloys. Acta Metall Sin, 2017, 53(11): 1487-1494.

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Abstract

The process of production and working environment of heat exchangers call for materials with good elevated temperature properties. However, the previous investigations were mainly focused on their room temperature properties. The relationship between microalloying and high temperature properties, especially creep properties of Al-Mn-based alloys are barely discussed. In order to improve the industrial applications of Al-Mn-based alloys, the effect of Mg, Ni and Zr additions and annealing process on the microstructure and high temperature properties of Al-Mn-based alloys were studied in this work. The investigated alloys were treated in two ways, first one is cold-rolling and heat treatment at 873 K for 10 min, and the second one is cold-rolling, heat treatment at 623 K for 1 h and 873 K for 10 min. The results indicate that annealing process has remarkable effect on the grain shape, fine equiaxed crystal grains are obtained in the former, while stable elongated grains are obtained for precipitation precedes recrystallization at 623 K in the latter. With Mg addition, more AlMnSi phase precipitated during annealing. The addition of Zr and Ni increases the type and amount of heat resistant compounds, precipitate Al₃Zr and AlMnSiNi, which are beneficial to improving high temperature properties of Al-Mn alloy. Al-Mn-0.3Mg-0.2Ni alloy has the best elevated temperature properties, and the tensile strength of it is 102 MPa (50 MPa higher than Al-Mn alloy) at 523 K. And the steady-creep rate is strongly decreased to 3.93×10^-8 s^-1, two orders of magnitude smaller than Al-Mn alloy at the temperature of 523 K under the stress of 40 MPa. With dispersoids compli cated or increased, the movement of dislocations are pinned strongly, which are contribute to improving the creep properties of Al-Mn alloy for the creep is mainly controlled by dislocation climb.

Key words: Al-Mn alloy alloy element microstructure control creep resistance

Received: 06 January 2017

ZTFLH:

TG146.2

Fund: Supported by Science Foundation of Jiangsu Key Laboratory for Advanced Metallic Materials (No.BM2007204)

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	Xiancui LIU
	Ye PAN
	Zhijiao TANG
	Weiqiao HE
	Tao LU

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https://www.ams.org.cn/EN/10.11900/0412.1961.2017.00010 OR https://www.ams.org.cn/EN/Y2017/V53/I11/1487

Table 1 Chemical compositions of the samples (mass fraction / %)

Fig.1 Schematic of specimen geometry in creep test (unit: mm)

Fig.2 OM images of microstructures in cold-rolling alloys S1 (a), S2 (b), S3 (c) and S4 (d) heat treated at 873 K for 10 min

Fig.3 Start precipitation and recrystallization curves of four alloys (Pre.—precipitation, Recry.—recrystallization)

Fig.4 OM images of microstructures in cold-rolling alloys S1 (a), S2 (b), S3 (c) and S4 (d) heat treated at 623 K for 1 h and 873 K for 10 min

Fig.5 TEM images of dispersoids in S1 (Inset shows the corresponding SAED pattern) (a), S2 (b), S3 (Inset shows the particles of Al₃Zr) (c) and S4 (d) alloys

Fig.6 EDS analyses of particles A in Fig.5a (a) and D in Fig.5d (b)

Fig.7 Tensile results of four alloys at 473 K (a) and 523 K (b)

Table 2 Steady-state creep rates of four alloys at temperatures of 473 and 523 K under the stress of 40 MPa (s^-1)

Fig.8 Creep curves of four alloys under 473 K (a) and 523 K (b)

Fig.9 TEM image of Al-Mn alloy under the creep temperature of 473 K and the stress of 40 MPa

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