Microstructural evolution and mechanical properties of a nickel-based honeycomb sandwich

Microstructural evolution and mechanical properties of a nickel-based honeycomb sandwich Qiuming Zhang, Xiaodong He Center for Composite Materials, Harbin Institute of Technology, Harbin 150001, PR China ARTICLE DATA Article history: Received 14 July 2008 Accepted 28 August 2008 Keywords: Microstructure evolution Mechanical properties Nickel-based honeycomb sandwich High-temperature brazing ABSTRACT A nickel-based superalloy honeycomb sandwich was manufactured by high-temperature brazing. The microstructural evolution and the out-of-plate mechanical properties were determined for honeycomb sandwiches aged at 800 C. The maximum tensile strength was 28.5 MPa and the compressive yield strength was 29.6 MPa for the original specimens. These parameters decreased to 24.7 MPa and 23.5 MPa for specimens aged for 10 h, to 24.9 MPa and 21.5 MPa for specimens aged for 20 h and to 26 MPa and 24.8 MPa for specimens aged for 30 h, respectively. With increased aging time the tensile elongation decreased, the intermetallic compounds and the eutectic structure in the brazing region disappeared, and the solid solution approaching the matrix gradually increased. 2008 Elsevier Inc. All rights reserved. 1. Introduction For the design and construction of lightweight transportation systems such as satellites, aircraft, high-speed trains and fast ferries, structural weight-saving is a major consideration. To meet this requirement, sandwich construction is frequently used instead of increasing the material thickness. Nickelbased superalloys have been used as materials for sandwich facings and cores that operate at a high-temperature. Several core shapes and types of core material have been applied to the construction of sandwich structures. Among them, a honeycomb core consisting of very thin foil in the form of hexagonal cells perpendicular to the facings is the most popular. Superalloy honeycombs are very important parts in advanced metallic thermal protection systems and their performance influences the economic efficiency and security of these systems. Witherell [1] performed an extensive theoretical study for the structural design of an air-cushion vehicle-hull structure using aluminum honeycomb sandwich panels. Okuto et al. [2] demonstrated the validity of the so-called equivalent plate thickness method in which a honeycomb sandwich panel subjected to in-plane loads was approximately replaced by a single-skin panel with equivalent plate thickness. Elastoplastic bending behavior of sandwich panels was studied by Kobayashi et al. [3]. Yeh and Wu [4] investigated the buckling strength characteristics of aluminum honeycomb sandwich panels in axial compression. The characteristics of the energy absorption capacity of bare honeycomb cores under lateral crushing loads was studied by Kunimoto et al., both theoretically and experimentally [5,6]. The dynamic properties and failure behavior of composite sandwich structures are complex and test programs are destructive, time-consuming and consequently expensive for industry [7,8]. An experimental study of the impact response of metallic cellular materials was carried out by Zhao et al. [9]. Metallic sandwich panels with textile cores were subjected to combined bending and shear and then designed for minimum weight [10]. The fatigue crack growth behavior of Ni-base honeycomb panels was studied at room temperature [11]. The longitudinal shear deformation behavior and failure mode of aluminum alloy honeycomb cores were investigated using single-block shear tests [12]. The Corresponding author. Postal address: No. 2, Yikuang Street, Nangang District, Science Park of Harbin Institute of Technology, A Building, 415 Room, Harbin, Heilongjiang Province, PR China; 150086. Tel./fax: +86 451 86402345. E-mail address: zqmingc289@163.com (Q. Zhang). 1044-5803/$ see front matter 2008 Elsevier Inc. All rights reserved. doi:10.1016/j.matchar.2008.08.013

179 Fig. 1 Fabrication of the honeycomb core. bending performance of a sandwich construction with thin cellular metal cores was measured and simulated [13]. Diffusion inevitably occurs in the joint region of honeycomb sandwiches at a high-temperature, which may change the mechanical properties of the structure. To stabilize the structure of nickel-based superalloy honeycomb sandwiches, it is thus essential to understand the microstructural evolution and changes in the mechanical properties. For this reason, a honeycomb sandwich was fabricated from a nickel-based superalloy by high-temperature brazing and its microstructural evolution and mechanical properties were investigated after aging at 800 C. 2. Materials and Methods A nickel-based superalloy was used for the honeycomb core and for the two face sheets comprising the sandwich sample. The cell shape of the honeycomb core was a regular hexagon, with each side 4 mm in length. The honeycomb cores were prepared by a sheet crimping process, as shown in Fig. 1. The stacked sheets were bonded by laser welding and the cores were cut and adhesively bonded to the face sheets to create the sandwich panel by high-temperature brazing. The wall thickness of the core and face sheet was 0.09 mm and Fig. 2 Micrograph of the nickel-based honeycomb sandwich in section. Fig. 3 Micrograph of the nickel-based honeycomb sandwich in cross-section.

180 MATERIALS CHARACTERIZATION 60 (2009) 178 182 0.225 mm, respectively; Brazing was conducted with BNi 2 at 1050 C and the braze was applied uniformly over the sheets. Capillary action drew the braze metal into the joints, resulting in an excellent bond. During the joining process, a low pressure of approximately 20 kpa was applied to the sample to ensure close contact between the face sheet and the honeycomb core. Specimens of the nickel-based honeycomb sandwich were aged in a muffle furnace at 800 C for aging times of 10, 20 and 30 h. Compressive and tensile tests were carried out on a universal material testing machine (Instron 5569) at room temperature. 3. Results and Discussion Fig. 4 Micrograph of the nickel-based honeycomb aged for 10 h. Fig. 5 Micrograph of the nickel-based honeycomb aged for 30 h. A section and cross-section of the nickel-based honeycomb sandwich are shown in Figs. 2 and 3, respectively. The face sheet of the honeycomb sandwich is marked I, the core is marked II and the brazing region is marked III. Metallographic results for the nickel-based honeycomb aged at 800 C for 10 and 30 h are shown in Figs. 4 and 5, respectively. The region approaching the matrix is a solid solution and there are intermetallic compounds and a eutectic structure in the middle of the brazing region. According to the metallographic results, for brazing clearance of less than 20 μm no intermetallic compounds or eutectic structure were present in the brazing seam, confirming that the critical brazing clearance was 20 μm. An XRD pattern for the brazing region is shown in Fig. 6, indicating that there are many intermetallic compounds in the brazing region, such as Ni 2 Si 3, BCr and Cr 2 Ni 3, and so on. A tensile fractograph for the original honeycomb sandwich is shown in Fig. 7; tensile fractographs for specimens aged for 10, 20 and 30 h are shown in Figs. 8 10, respectively. In all tensile specimens, fracture occurred wholly within the honeycomb core and no interface separation was observed, indicating that the brazing process was satisfactory. The outof-plate tensile mechanical properties of the honeycomb sandwich are shown in Fig. 11. The original as-fabricated specimen had a maximum tensile strength of 28.5 MPa, a tensile elastic modulus of 128 MPa and tensile elongation of 28.5%. After aging at 800 C, these parameters were 24.7 MPa, 357 MPa and 17.11%, 24.9 MPa, 319 MPa and 11%, and 26.0 MPa, 496 MPa and 7.5% Fig. 6 XRD pattern for the brazing region.

181 Fig. 7 Tensile fractograph of the original honeycomb sandwich. for specimens aged for 10, 20 and 30 h, respectively. No obvious plastic deformation was observed in the tensile curve of the original specimen. Compared to the original samples, the tensile mechanical properties changed after aging: the maximum tensile strength decreased by more than 8.5%, the tensile modulus increased by more than 149% and the tensile elongation decreased by more than 39%. The decrease in the maximum tensile strength of specimens aged at 800 C can be seen in Fig. 11. The compressive properties of the honeycomb sandwich are shown in Fig. 12. The compressive elastic modulus of the original specimen was 223 MPa and the maximum yield strength was 29.6 MPa; these parameters were 245 MPa and 23.5 MPa, 391 MPa and 21.4 MPa, and 292 MPa and 24.8 MPa after aging at 800 C for Fig. 9 Tensile fractograph of the honeycomb sandwich aged for 20 h. 10, 20 and 30 h, respectively. Compared to the original specimens, aging for 10, 20 and 30 h increased the compressive elastic modulus of specimens by approximately 10%, 75% and 31%, and decreased the yield strength by 21%, 28% and 31%, respectively. These results indicate that the microstructure of the honeycomb sandwich changed greatly during aging at 800 C for the first 10 h; longer aging did not lead to further significant changes in the microstructure, so the mechanical properties did not change greatly. The nickel-based honeycomb sandwich exhibited the tensile characteristics shown in Fig. 11, with no obvious plastic deformation. This characteristic was confirmed by tensile fracture of the honeycomb sandwich. Tensile fracture Fig. 8 Tensile fractograph of the honeycomb sandwich aged for 10 h. Fig. 10 Tensile fractograph of the honeycomb sandwich aged for 30 h.

182 MATERIALS CHARACTERIZATION 60 (2009) 178 182 of the honeycomb core was obviously brittle and no dimples were observed. Boundaries between the matrix and the brazing region were evident, as shown in Figs. 2 and 3. With increasing aging time, the boundary became indistinct, the intermetallic compounds and eutectic structure in the middle of the brazing region disappeared, and the solid solution zone approaching the matrix gradually increased, as shown in Figs. 4 and 5. This was also observed during tensile fracture, as shown in Figs. 8 10. The fracture characteristics of the solid solution zone approaching the matrix are obviously different from those of the matrix, so the solid solution zone can easily separate from the matrix. 4. Conclusions A nickel-based honeycomb sandwich was manufactured and the microstructural evolution and the change of properties were studied. The original specimens had the following properties: tensile elastic modulus, 128 MPa; maximum tensile strength, 28.5 MPa; elongation, 28.5%, compressive elastic modulus, 223 MPa; and maximum yield strength, 29.6 MPa. Specimens aged at 800 C for 10 h had the following properties: tensile elastic modulus, 357 MPa; maximum tensile strength, 24.7 MPa; elongation, 17.11%; compressive elastic modulus, 245 MPa; and maximum yield strength, 23.5 MPa. Specimens aged at 800 C for 20 h had the following properties: tensile elastic modulus, 319 MPa; the maximum tensile strength, 24.9 MPa; elongation, 11%; compressive elastic modulus, 391 MPa; and maximum yield strength, 21.5 MPa. Specimens aged at 800 C for 30 h had the following properties: tensile elastic modulus, 496 MPa; maximum tensile strength, 26 MPa; elongation, 7.5%; compressive elastic modulus, 292 MPa; and maximum yield strength, 24.8 MPa. With increasing aging time, the solid solution zone approaching the matrix increased and the intermetallic compounds and eutectic structure in the middle of the brazing region gradually decreased. Plastic deformation was not Fig. 11 The tensile stress versus strain curves of the honeycomb sandwich. Fig. 12 The compressive stress versus strain curves of the honeycomb sandwich. observed in any of the tensile curves, which was confirmed by the tensile fracture behavior. REFERENCES [1] Witherell PW. Air cushion vehicle structural design methods. Masters thesis, The George Washington University, December 1977. [2] Okuto K, Namba K, Mizukoshi H, Hiyama Y. The analysis and design of honeycomb welded structures. J Light Met Welding 1991;29:361 8. [3] Kobayashi H, Daimaruya M, Okuto K. Elastoplastic bending deformation of welded honeycomb sandwich panel. J Jpn Soc Mech Eng 1994;60:1011 6. [4] Yeh WN, Wu Y. Enhancement of buckling characteristics for sandwich structure with fiber reinforced composite skins and core made of aluminum honeycomb and polyurethane foam. J Theor Appl Fract Mech 1991;15:63 74. [5] Kunimoto T, Yamada H. Study on the buffer characteristics of the honeycomb sandwich construction under dynamic loading. J Light Metals 1987;37:327 31. [6] Kunimoto T, Mori N. Study on the buffer characteristics of the corrugated-core used for the 5051 aluminum alloy sandwich construction under dynamic loading. J Light Metals 1989;39:687 92. [7] Wada A, Kawasaki T, Minoda Y, Kataoka A, Tashiro S, Fukuda H. A method to measure shearing modulus of the foamed core for sandwich plates. J Compos Struct 2003;60:385 90. [8] Lopatnikov SL, Gama BA, Haque MJ, Krauthauser C, Gillespie JW, Guden M, et al. Dynamics of metal foam deformation during Taylor cylinder Hopkinson bar impact experiment. J Compos Struct 2003;61:61 71. [9] Zhao H, Elnasri I, Abdennadher S. An experimental study on the behaviour under impact loading of metallic cellular materials. Int J Mech Sci 2005;47:757 74. [10] Zok FW, Rathbun HJ, Wei Z, Evans AG. Design of metallic textile core sandwich panels. Int J Solids Struct 2003;40:5707 22. [11] Liu L, Holmes JW. Experimental investigation of fatigue crack growth in thin-foil Ni-based sandwich structures. Int J Fatigue 2007;29:1452 64. [12] Pan SD, Wu LZ, Sun YG, Zhou ZG, Qu JL. Longitudinal shear strength and failure process of honeycomb cores. J Compos Struct 2006;72:42 6. [13] Bart-Smith H, Hutchinson JW, Evans AG. Measurement and analysis of the structural performance of cellular metal sandwich construction. Int J Mech Sci 2001;43:1945 63.