DEENP - Departamento de Engenharia de Produção
URI permanente desta comunidadehttp://www.hml.repositorio.ufop.br/handle/123456789/556
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Resultados da Pesquisa
Item Interface evaluation of a Bi–Zn eutectic solder alloy : effects of different substrate materials on thermal contact conductance.(2021) Azeredo, Rudimylla Septimio; Cruz, Clarissa Barros da; Xavier, Marcella Gautê Cavalcante; Lima, Thiago Soares; Garcia, Amauri; Spinelli, José Eduardo; Cheung, NoéIndustry is searching for ways of improving the process control required for the manufacture of electronic circuitry. In this respect, a numerical mathematical model for thermal contact conductance of solder/substrate couples is developed based on an inverse heat conduction problem. The intention of this research is combining the model results and wetting experiments in order to determine if there is a compromise between them in the matter of the Bi–Zn eutectic alloy. Substrate materials considered as priority for the electronics industry were tested. It was found that the heat transfer coefficients (h) and the contact angles (θ) might be related to each other. The Bi–Zn/copper, Bi–Zn/nickel, Bi–Zn/Invar and Bi–Zn/steel couples, in this order, generated θ varying from the smallest to the largest as well as h from the largest to the smallest. Microstructural coarsening effect has been realized with higher spacing between Zn fibers (λZn) referring to a condition of worse heat extraction imposed by an alloy/substrate couple during solidification.Item Interfacial heat transfer and microstructural analyses of a Bi- 5% Sb lead- free alloy solidified against Cu, Ni and low-C steel substrates.(2021) Lima, Thiago Soares; Cruz, Clarissa Barros da; Xavier, Marcella Gautê Cavalcante; Reyes, Rodrigo André Valenzuela; Bertelli, Felipe; Garcia, Amauri; Spinelli, José Eduardo; Cheung, NoéBi-Sb system alloys demonstrate high corrosion resistance and good wettability, becoming promising for use as lead-free solder alloys. The simplicity of the phase diagram is also a characteristic of this system, which is isomorphous forming the (Bi,Sb) phase. While extensive research has been performed on heat flow in couples of microelectronics surfaces with eutectic and peritectic alloys, literature regarding the issues of interfacial heat transfer between isomorphous alloys and microelectronics substrates is nonexistent. In this regard, the present research work demonstrates not only the application of a numerical mathematical model for thermal interface conductance but also wetting and interfacial reaction layer results in the formation of phases for the Bi- 5 wt% Sb alloy in different substrate materials. After carrying out the mentioned analyzes in three different conditions, Bi-Sb/copper, Bi-Sb/nickel and Bi-Sb/low-C steel, the wetting angle is shown not to be the predominant factor in controlling the interfacial heat transfer. Instead, the phases forming the interfacial layer from each of the tested substrates have a role in the heat transfer coefficients (h). In the case of the steel substrate, there is no layer formation, which allows greater contact conductance, whereas Bi-Sb/copper and Bi-Sb/nickel couples generate smaller h, being reasonably similar to each other.Item Plate-like growth in a eutectic Bi–Ni alloy : effects of morphological microstructure evolution and Bi3Ni intermetallic phase on tensile properties.(2020) Cruz, Clarissa Barros da; Lima, Thiago Soares; Kakitani, Rafael; Barros, André dos Santos; Garcia, Amauri; Cheung, NoéThe development of efficient thermal interface materials (TIMs) has become an emerging demand mainly driven by the continual rise in power dissipation of high-performance microprocessors. In this context, Bi-based alloys are among the promising types of TIMs for electronic packaging applications. However, the influence of the microstructural arrangement on mechanical strength of Bi–Ni alloys remains barely understood. To overcome this issue, this study aims to develop quantitative microstructure features-tensile properties correlations for a Bi–0.28 wt.%Ni alloy solidified in a wide range of cooling rates (T). ̇ In addition to the phase diagram calculated by the Thermo-Calc software (SSOL6 database) and differential scanning calorimetry analysis, the characterization of the Bi3Ni intermetallic compound is carried out using X-ray diffraction and SEM microscopy with energy disper- sive X-ray spectroscopy. Wavy instabilities in the plate-like morphology of the Bi matrix are shown to occur for T ̇ ≤ 0.13 ◦C/s. Besides that, more significant variations in yield and ultimate tensile strengths, y and u, respectively, are associated with a certain range of microstructural spacings between Bi plates () from 47.6 to 135.2m. Hence, Hall–Petch type relations are proposed to describe the variation of both y and u as a function of .