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Heading of a small bi-metallic components for electric contacts

Wybrane pełne teksty z tego czasopisma
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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Electrical connectors mostly have silver contacts joined to the supplying and discharging electric current elements by riveting. In order to reduce costs, the rivet core of the contact can be replaced with a cheaper material such as copper. There is a wide range of commercially offered bi-metallic, silver-copper rivets available for the production of contacts. This generates a new situation in the riveting process, as the bi-metallic rivet is to be formed. In the analyzed example it is a small-sized object that places it near the limits of micro-forming. The riveting process was originally designed by classical upsetting. It was based on the results of FEM simulation taking into account the deformation of three materials included in the joint: two materials for rivet and sheet material. The FEM results were verified by the results of experimental studies indicating high compliance. The elimination method of the elastic deformations of the load system impact on the process forces was elaborated and it was used for comparative analysis with the force run obtained from FEM. The model simulating the working conditions of the connector was developed. Based on the joint load modeling results, the cause of possible delamination of constituent materials was determined. It was also defined the desired silver distribution in the connector head to eliminate the risk of separation of both materials during exploitation.
Słowa kluczowe
Wydawca
Rocznik
Strony
41--48
Opis fizyczny
Bibliogr. 23 poz., rys.
Twórcy
  • Institute of Manufacturing Technologies, Warsaw University of Technology, Narbutta 85, 02-524 Warsaw, Poland
autor
  • Institute of Manufacturing Technologies, Warsaw University of Technology, Narbutta 85, 02-524 Warsaw, Poland
Bibliografia
  • Essaa, K., Kacmarcik, I., Hartley, P., Plancak, M., Vilotic, D.,2012, Upsetting of bi-metallic ring billets, Journal of Materials Processing Technology 212, 817- 824.
  • Geiger, M., Kleiner, M., Eckstein, R., Tiesler, N., Engel, U., 2001, Microforming, CIRP Annals – Manufacturing Technology, 50 (2), 445-462.
  • Geiger, M., Messner, A., Engel, U., 1997, Production of microparts – Size effects in bulk metal forming, similarity theory, Production Engineering, 4, 55-58.
  • Green e-motion project, 2016, Paris Declaration on Electro Mobility and Climate Change & Call to Action; www.greenemotion-project.eu
  • Kazanowski, P., Misiołek, W.Z., Epler, E.E., 2004, Bi-metal rod extrusion—process and product optimization, Materials Science and Engineering, A369, 170-180
  • Kocanda, A, Presz, W., Mazurek, W., Adamczyk, G., 2001,Contact pressure distribution in upsetting of compound metals, Journal of Materials Processing Technology, 60,44-48.
  • Muster, A., Presz, W., 1999, Influence of initial surface roughness on galling behavior of steel-steel couple, Scandinavian Journal of Metallurgy, 28 (1), 5-8.
  • Olejnik, L., Presz, W., Rosochowski, A., 2009, Backward Extrusion using Micro-Blanked Aluminium Sheet, International Journal of Material Forming, 2, 1, 617-620.
  • Paris Declaration on Electro Mobility and Climate Change & Call to Action, 2015, Lima – Paris.
  • Politis, D.J., Lin, J., Dean, T.A., Balint, D.A., 2014, An investigation into the forging of Bi-metal gears, Journal of Materials Processing Technology, 214, 2248– 2260.
  • Presz, W., Cacko, R., 2011, Influence of Micro-Rivet Manufacturing Process on Quality of Micro-Joint, Proc. 14th Int.Conf. on Material Forming, Esaform 2011, Belfast, American Institute of Physics Conf. Proc. 1353, 1, 541-546.
  • Presz, W., Cacko, R., 2017, Ultrasonic assisted microforming, 26th Int. Conf. on Metallurgy and Materials, METAL, Brno, 2017, 521-526
  • Presz, W., Cacko, R., 2018a, Bimetallic Micro-Punches forMicro-Blanking Processes, Archives of Metallurgy and Materials, 63, 29-34.
  • Presz, W., Cacko, R., 2018b, Determination of material distribution in heading process of small bimetallic bar, AIP Conference Proceedings, 1960, 050014.
  • Presz, W., Rosochowski, A., 2006, The influence of grain size on surface quality of microformed components, The 9th Proc. Int. Conf. on Materials Forming, ESAFORM 2006, Glasgow, 587-590.
  • Presz, W., Rosochowski, M., 2017, Application of semiphysical modeling of interface surface roughness in design of pre-stressed microforming dies, Int. Conf. on the Technology of Plasticity, ICTP 2017, Procedia Engineering, 207, 1004-1009.
  • Presz, W., 2016, Scale effect in design of the pre-stressed microdies for microforming, Computer Methods in Materials Science, 16, 196-203.
  • Raulea, L.V., Goijaerts, A.M., Govaert, L.E., Baaijens, F.P.T., 2001, Size effect in the processing of thin metal sheets, Journal of Materials Processing Technology, 115, 44-48.
  • Stress-Strain Curves, 2002, Material Park, OH 44073-0002.
  • Tiesler N., 2002, Microforming - Size effects in friction and their influence on extrusion processes, Wire, 52, 1, 34-38.
  • Wang, Ch., Guo, B., Shan, D., Zhang, M., Bai, X., 2014, Tribological behaviors in microforming considering microscopically trapped lubricant at contact interface, Journal of Advanced Manufacturing Technology, 71, 2083-2090.
  • Yueqing Hawin Electric Co., Ltd., https://hawin.en.alibaba.com/.
  • Wenzhou Saijin Electrical Alloy Co., Ltd., https://saijinele.en.alibaba.com/
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-c56ae02f-f306-4b5f-a28f-507d960d2ccf
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