Article ID: 1003-6326(2005)02-0275-05
Preparation and mechanical properties of
Ni-Cr-Al alloy by EB-PVD
GUAN Chun-long(关春龙), HE Xiao-dong(赫晓东), LI Yao(李 垚)
(Center for Composite Materials, Harbin Institute of Technology, Harbin 150001, China)
Abstract: Ni-Cr-Al alloy was deposited by electron beam-physical vapor deposition(EB-PVD) method. The microstructure was investigated on as-deposited and long-term aged alloy. The results indicate that grain on surface of as-deposited alloy is about 185nm in size, and a laminated structure in cross-section is observed. However, after aging for 16 and 120h at 760℃, the laminated structure is dissolved, and the individual grain can be seen clearly. Columnar crystals form on the evaporation side, and exquiaxed grains form on the substrate side. The major precipitate is γ′ phase after prolonged aging at 760℃. Mechanical properties of the Ni-Cr-Al alloy were also studied. The results show that the fracture of as-deposited alloy has mixed type at room temperature, and intergranular fracture among columnar crystals is observed. Compared to that of as-deposited alloy, fracture of alloy after aging for 16 and 120h at 760℃ appears to involve ductile fracture with dimples.
Key words: Ni-Cr-Al alloy; physical vapor deposition; microstructure; mechanical properties; columnar crystal CLC number: TG146.2
Document code: A
1 INTRODUCTION
Ni-based superalloys are presently used as gas turbine components in power plants and in aircraft engines[1-3]. Since 1970s, Al has been added to Ni-Cr alloy for producing the hard elastic alloys used as wear resistant components in instruments[4]. This is an important development in Ni-Cr alloy. With the increasing demands for the alloys with high hardness and toughness, Ni-Cr-Al alloys are designed to meet the requirement. Due to the addition of Ce element, forgeable temperature was decreased, and grains were refined, and the inclusions were removed[5].
LIU[6, 7] have preformed extensive research on the behavior of Ni-Cr-Al hard elastic alloy. Their results indicated that a number of Cr (α )-rich phase were found around γ′ phase with tiny grains and dispersed distribution when aged at 550℃ for 5h. But Cr (α )-rich phase was not observed in this work. Ni-Cr-Al alloys were usually produced by vacuum melting and cast process. But reports about Ni-Cr-Al alloy prepared by electron beam-physical vapor deposition(EB-PVD), which is often used to produce the thermal barrier coatings (TBCs)[8-11], are few.
Electron beam-physical vapor deposition(EB-PVD) technology is a potential technique for producing near theoretical density and oxide-free condensates[12-14]. Due to its high deposition rate, easy control for chemical constitution and pollution-free to environment, Ni-Cr-Al alloy with 0.5 mm in thickness was deposited by EB-PVD process. In this work, microstructure and mechanical properties of an EB-PVD formed Ni-Cr-Al alloy are studied.
2 EXPERIMENTAL
Ni-Cr-Al alloy was prepared by EB-PVD. The chemical composition of Ni-Cr-Al ingots is Ni-22Cr-5Al-0.6Y(mass fraction, %). The process of the preparation of deposited alloy by EB-PVD is shown in Fig.1.
Before the alloy was fabricated, the resistance adhesive layer with about 15μm in thickness should be deposited to prevent bonding between substrate and condensate. The Ni-Cr-Al ingots of 100mm in diameter and 200mm in length were filled in a water-cooled crucible. A stainless steel disk substrate of 800mm in diameter and 20mm in thickness was mounted on the vertical axis. The substrate was heated by electron beam and the temperature was kept at 900℃. The degree of vacuum was 5 ×10-4Pa during evaporation. Thickness of the alloy could be controlled by adjusting the beam current, the upward speed of the ingots and rotation speed of the substrate. The rotation speed of the substrate was 36r/min. The deposition rate of the alloy was 1.8 μm/min. In this work, the Ni-Cr-Al alloy with 0.5mm in thickness was prepared by EB-PVD, and aged at 760℃ for 16 and 120h.
Fig.1 Schematic diagram of EB-PVD process of Ni-Cr-Al alloy
The SEM samples of the tested alloy were ground to 13μm and mechanically polished, then etched with a solution of HCl, HNO3, HF and H2O. The TEM samples were mechanically thinned down to 50-100 μm in thickness, and electropolised with a solution of 7% perchloric acid and ethanol at -30--20℃ by a double jet electropoliser. Tensile tests at room temperature were carried out by Instron-5500.
3 RESULTS AND DISCUSSION
3.1 Microstructures of tested alloy
Microstructures in the deposited condition are shown in Fig.2. Based on the AFM and TEM images given in Fig.2, grain size on the surface of vapor-deposited alloy is in the range of 70 - 255nm, and average size is about 185nm. However, average size of the alloy annealed at 760℃ for 16h is about 4 μm(Fig.3(a)). Convergent beam diffraction shows that the as-deposited alloy has single phase and a laminated structure is observed in the cross-section of as-deposited alloy, as shown in Fig.2(b). After annealing at 760℃ for 16h, the laminated structure dissolves and the individual grain can be seen clearly. Schulz et al[15] EB-PVD-deposited a ceria-stabilized TBC by one-source and two-source jumping evaporation. A lamellar structure was also observed in the cross-section, which can be attributed to the difference in vapor pressure of ceria and zirconia. Therefore, it can be concluded that in this study the laminated structure in cross-section can be contributed to the difference in vapor pressure of nickel, chromium and aluminum.
Fig.2 Microstructure of as-deposited Ni-Cr-Al alloy
Columnar crystals form on the evaporation side, and exquiaxed grains form on the substrate side(Fig.3(b)). Formation of columnar crystals attributes to the substrate with lower temperature, the higher evaporation rate of alloys and the substrate with higher degree of coarseness. The surface of substrate has some degree of coarseness, namely some positions can protrude. When vapor atoms touch these positions, preferential nucleation will occur. Furthermore, the substrate temperature and the rate of migration of deposited atoms are lower. In addition, due to the higher evaporation rate of alloys, the atoms deposited to the substrate will grow quickly along certain direction. As a result, the microstructure of as-deposited alloy is columnar crystals. The major precipitates are γ′phase during prolonged aging at 760℃. Morphologies of alloy γ′ phase in alloy aged at 760℃ for 16 and 120h are shown in Fig.4. With an increase in aging time, γ′precipitates grow rapidly. The average size of γ′particles is about 30 and 45nm respectively.
Fig.3 Microstructures of Ni-Cr-Al alloy annealed for 16h
Fig.4 TEM micrographs of γ′ phase in alloy aged at 760℃ for different time
3.2 Mechanical properties of tested alloy
The SEM fractographs of the tensile samples as-deposited and aged at 760℃ for 16 and 120h are given in Fig.5. Fractographs of the as-deposited alloy show that a typical brittle fracture takes place along boundaries of columnar crystals formed in the substrate side (zone A in Fig.5(a)). This contributes to the weak boundaries among columnar crystals. As shown in zone B in Fig.5(a), though the exquiaxed dimples with little depth are dominant in this region, and some pores are observed. Furthermore, there are no tearing ribs. Therefore, elongation value is less than 1%. With increasing aging time, a brittle-to-ductile transition occurs. The fractographs of samples aged at 760℃ for 16 and 120h indicate an obvious ductile fracture with a lot of dimples, and elongation values increase to more than 10%.
The tensile stress—strain behavior of as-deposited and annealed specimens is shown in Fig.6. The room temperature tensile strength of EB-PVD processed alloy decreases from 1625MPa in as deposited condition to 831MPa after annealing at 760℃ for 120h. Yield strengths of the EB-PVD processed deposits are measured to be 791.8 and 757.3MPa after annealing for 16 and 120h at 760℃, respectively. It can also be noted from Fig.6 that no yielding is observed in the as-deposited alloy. The as-deposited material shows no sign of plastic deformation whereas annealed material shows a ductile behavior. The mechanical properties of EB-PVD formed Ni-Cr-Al alloy in this study are similar to those of Ni3Al materials deposited using vacuum plasma spraying by Tiwari and his co-workers[16].
Fig.5 Fractographs of as-deposited and annealed Ni-Cr-Al alloy
Fig.6 Stress—strain behavior of as-deposited and annealed EB-PVD deposits
4 CONCLUSIONS
This study illustrates the potential of producing Ni-Cr-Al alloy sheet with perfect mechanical properties by EB-PVD. Ni-Cr-Al alloy with average grain size of 185nm is deposited using EB-PVD, and a laminated structure in cross-section is observed. After aging for 16 and 120h at 760℃, grain on surface grows, and the laminated structure disappears. The major precipitates are γ′phase during prolonged aging at 760℃, and γ′phase size increases with aging time. Fractograghs of vapor-deposited alloy show that the fracture is mixed type. Brittle fracture takes place along boundaries of columnar crystals formed on substrate side. However, the equiaxed dimples are dominant on the evaporation side. As-deposited alloy has relatively low ductility and no sign of plastic deformation, whereas the annealed alloys show a ductile behavior and higher ductility.
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Foundation item: Project(2002AA763020) supported by the Hi-tech Research and Development Program of China
Received date: 2004-11-15; Accepted date: 2005-01-18
Correspondence: GUAN Chun-long, PhD; Tel: +86-451-89678120; E-mail: gcl_hit@163.com
(Edited by YANG Bing)
