Numerical analysis of the Temperature Distribution in Centrifugal Casting

Year 2019, Volume: 3 Issue: 1, 1 - 7, 29.03.2019

İredia Erhunmwun John Akpobi Toyin Osunde

Abstract

This paper entails
the mathematical modelling of the conductive heat transfer in horizontal
centrifugal casting. The model was then used to analyse the temperature
distribution in centrifugal casting. The Finite Element Method was used to
discretize and analyse the temperature distribution. Four quadratic element was
used to represent the entire domain of the casting and mould region
respectively. The result obtained shows the temperature distribution both in the
liquid cast region and the mould region. The liquid cast was poured into the
prepared mould at the temperature of 1500⁰C
and the mould was preheated to a temperature of 250⁰C to prevent thermal shock. After about 20 secs when
the liquid cast has been poured into the mould, the result obtained shows a decrease
in temperature from 1388.7295⁰C
at a distance of 4.5cm to 1032.8636⁰C at a distance of 6.5cm from
the centre of the mould. Also in the mould region, after about 20 secs, the
temperature drops from 755.8252⁰C at 6.5cm to 350.6205⁰C
at 15.5cm from the centre of the mould. The maximum percentage error was 1.6627% and the minimum percentage error
was 0.0069%. This comparison was made
for the temperature distribution in the cast region and the mold region after
about 20 secs when the molten metal
has been poured into the mold cavity. This shows that the result obtained from
this research is in agreement with the result obtained from finite difference
method.

Keywords

Centrifugal Casting, Finite Element Method, Heat Transfer, Discretization, Conduction

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