Abstract
Zr-Cu filler metal is proposed for SiC ceramic under special working conditions, as a novel type of the active filler metal, the difference of physical and chemical properties between SiC ceramic and Zr-Cu filler metal leads to greater residual stress in the joint, which affects the mechanical properties of brazing SiC ceramic joint. Based on the finite element method (FEM) simulation, the residual stress of the joint is simulated to guide the design of Zr-based filler metal and formulation of brazing process. The residual stress distribution of SiC ceramic joints brazed at 1200 °C with different thickness of the filler metal and cooling rate is simulated by ANSYS software. The simulation results of the residual stress are verified by brazing experiments and XRD measurements. The results show that the simulated residual stress of the joint is mainly axial compressive stress. The axial compressive stresses are the lowest when the filler metal thickness is 0.1 mm and the cooling rate is 2 °C /min, and increase with the increase of the filler metal layer thickness and cooling rate. The shear strength of the brazed SiC ceramic joint that achieves the highest with 2 °C /min is about 72 MPa, and then decreases with the increase of cooling rate. The experimental test of residual stress in different locations of the brazed SiC ceramic joint basically coincide with the FEM simulation.
Highlights
Modern ceramic materials are more and more widely used in the manufacturing industry with the rapid development of science and technology
The residual stresses distribution of the joint between SiC ceramic and Zr-Cu filler metal under brazing conditions is investigated by ANSYS software and verified by experimental test, which provides a foundation for the design and development of Zr-based filler metal and adjusting the residual stress of joints to obtain ideal brazed joint
The von Mises stress in the central region of SiC ceramic is the smallest from Figure 3b, and the von Mises stress gradually increases from the central region to the edge
Summary
Modern ceramic materials are more and more widely used in the manufacturing industry with the rapid development of science and technology. The experimental test and numerical simulation method are used for evaluating residual stress of SiC ceramic joints [8,9]. This study is mainly discussed the residual stress of SiC ceramic joint is analyzed by ANSYS simulation, and verified by experimental test. SiC ceramic, the residual stress distribution of the joint has an important influence on the design of Zr-based filler metal and formulation of joining process parameters for brazing SiC ceramic. The residual stresses distribution of the joint between SiC ceramic and Zr-Cu filler metal under brazing conditions is investigated by ANSYS software and verified by experimental test, which provides a foundation for the design and development of Zr-based filler metal and adjusting the residual stress of joints to obtain ideal brazed joint
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