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Modeling of the distribution of thermal fields during spark plasma sintering of alumina ceramics
The article shows the use of an experimental-calculation method for the refinement of thermoelectric constants of graphite materials and alumina ceramics by experimentally studying the heating of graphite equipment and refinement thermoelectric constants of materials using the finite element method...
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Published in: | IOP conference series. Materials Science and Engineering 2019-06, Vol.558 (1), p.12004 |
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container_title | IOP conference series. Materials Science and Engineering |
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creator | Berendeev, N N Popov, A A Pyaterikova, V V Boldin, M S Nokhrin, A V Chuvil'deev, V N Lantsev, E A |
description | The article shows the use of an experimental-calculation method for the refinement of thermoelectric constants of graphite materials and alumina ceramics by experimentally studying the heating of graphite equipment and refinement thermoelectric constants of materials using the finite element method (ANSYS WORKBENCH). To simulate the thermal fields of graphite equipment based of the data on electric current, voltage and heat exchange conditions, a coupled boundary electric and non-stationary temperature problem was realized. The application of the developed approach made it possible to clarify the thermoelectric constant of materials, which helped to reduce the difference between the experimental and simulated temperatures from 20 to 5%. |
doi_str_mv | 10.1088/1757-899X/558/1/012004 |
format | article |
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subjects | Aluminum oxide CAD Ceramics Computer aided design Finite element method Graphite Heat exchange Plasma sintering Spark plasma sintering Thermal simulation Thermoelectric materials |
title | Modeling of the distribution of thermal fields during spark plasma sintering of alumina ceramics |
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