Effects of Cu Content on the Microstructure and Tensile Property of K4061 Alloy

doi:10.11900/0412.1961.2022.00427

Acta Metall Sin

2024, Vol. 60

Issue (9): 1179-1188 DOI: 10.11900/0412.1961.2022.00427

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Effects of Cu Content on the Microstructure and Tensile Property of K4061 Alloy

CAO Shuting¹^,², ZHAO Jian³, GONG Tongzhao¹, ZHANG Shaohua¹(

), ZHANG Jian¹

^1.Shi -changxu Innovation Center for Advanced Materials, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China
^2.School of Materials Science and Engineering, University of Science and Technology of China, Shenyang 110016, China
^3.Xi'an Aerospace Propulsion Institute, Xi'an 710100, China

Cite this article:

CAO Shuting, ZHAO Jian, GONG Tongzhao, ZHANG Shaohua, ZHANG Jian. Effects of Cu Content on the Microstructure and Tensile Property of K4061 Alloy. Acta Metall Sin, 2024, 60(9): 1179-1188.

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Abstract

The LOX (liquid oxygen)/kerosene rocket engine is widely used in heavy launch vehicles owing to its low cost, high performance, and high reliability. However, the next-generation LOX/kerosene rocket engine requires a new superalloy that can resist oxygen-rich combustion. The K4061 alloy is a second-generation superalloy that has better resistance to oxygen-rich combustion compared to the first-generation superalloy due to the addition of the Cu element in its composition. However, there is limited research on the role of the Cu element in the superalloy. This study investigates the effect of Cu content (mass fraction) ranging from 1% to 10% on the microstructure and Cu distribution of K4061 alloy using thermodynamic calculations along with DSC, SEM, and TEM experiments. The results show that during the equilibrium solidification of K4061 alloy, the γ matrix precipitates first, followed by precipitating MC carbides at the end of solidification. The addition of Cu does not affect the equilibrium solidification path of the alloy; however, it lowers the solidus and liquidus temperatures of the alloy and the precipitation temperature of MC. During the nonequilibrium solidification, the δ phase is also precipitated at the late solidification stage. The types of precipitated phases of K4061 alloy with different Cu contents remain unchanged, consistent with thermodynamic calculations. However, Cu-rich phases are not found in the sample, and Cu does not dissolve in MC in large quantities or segregate into grain boundaries. TEM results show that Cu is enriched in the strengthening phases, and the size of the strengthening phases slightly increases with the addition of Cu during aging heat treatment. Additionally, the addition of Cu reduced the room temperature and 750°C tensile strength of the alloy.

Key words: Ni-base superalloy solidification precipitation Cu tensile property

Received: 31 August 2022

ZTFLH:

TG146.1

Fund: National Natural Science Foundation of China(52150233,52203301);Key Research Program of the Chinese Academy of Sciences(ZDRW-CN-2021-2-1)

Corresponding Authors: ZHANG Shaohua, associate professor, Tel: (024)23748882, E-mail: zhangshaohua@imr.ac.cn

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https://www.ams.org.cn/EN/10.11900/0412.1961.2022.00427 OR https://www.ams.org.cn/EN/Y2024/V60/I9/1179

Table 1 Nominal compositions of K4061 alloy

Fig.1 Calculated solidification sequences of K4061 alloy with different Cu contents predicted by Thermo-Calc
(a)K4061 (b)K4061-1Cu (c)K4061-2Cu (d)K4061-5Cu (e)K4061-8Cu (f)K4061-10Cu

Fig.2 Variations of solidification characteristic temperature with Cu content in K4061 alloy by Thermo-Calc

Fig.3 Heating (a) and cooling (b) DSC curves of K4061 alloy with different Cu contents

Fig.4 Variations of solidification characteristic temperature with Cu content measuring by DSC

Fig.5 SEM images of as-cast K4061 (a), K4061-2Cu (b), K4061-5Cu (c), K4061-8Cu (d), and K4061-10Cu (e) alloys

Fig.6 SEM images of K4061 (a), K4061-2Cu (b), K4061-5Cu (c), K4061-8Cu (d), and K4061-10Cu (e) alloys after heat treatment

Fig.7 SEM images of γ'/γ" phases in K4061 (a), K4061-2Cu (b), K4061-5Cu (c), K4061-8Cu (d), and K4061-10Cu (e) alloys after heat treatment

Fig.8 SEM images and corresponding EDS element maps of as-cast K4061-8Cu (a) and K4061-10Cu (b) alloys

Fig.9 TEM high-angle annular dark field (HAADF) image and corresponding element maps of the grain boundary in the K4061-10Cu alloy after heat treatment

Fig.10 TEM-HAADF image and corresponding element maps of the K4061-10Cu alloy after heat treatment

Table 2 Element contents of MC calculated by Thermo-Calc software

Fig.11 TEM image and EDS line scanning results of the K4061-10Cu alloy after heat treatment

Table 3 RT and 750^oC tensile properties of as-cast K4061 alloy with different Cu contents after heat treatment

Fig.12 Gibbs energies of γ' (a) and γ" (b) phases in K4061 alloy with different Cu contents

Fig.13 Influences of Cu content on the critical nucleation sizes of γ' and γ" phases

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