Modeling Heat Transfers in a Typical Roasting Oven of Burkina Faso

Physical Science International Journal Pub Date : 2021-12-27 DOI:10.9734/psij/2021/v25i1130290

D. Namoano, A. Compaoré, O. Ouédraogo, G. L. Sawadogo, Drissa Ouedraogo, S. Igo

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引用次数: 1

Abstract

This work concerns a numerical study of heat transfers in a typical roasting oven in Burkina Faso. The numerical methodology is based on the nodal method and the heat transfer equations have been established by performing a heat balance on each node. The equations obtained were then discretized using an implicit finite difference scheme and solved by the Gauss algorithm. The numerical results validated by the experiment show that the heat transfers within the oven are mainly influenced by the gas flow, the ambient temperature, the flame extinction time and the wind speed. Increasing gas flow rate and increasing ambient temperature increase the oven cavity temperature. The increase in wind speed causes a significant drop in the oven cavity temperature after the first 15 minutes of operation. Beyond a wind speed of 3m/s, we observe a convergence of the oven cavity temperatures towards a limit value. Regardless of the time the flame is extinguished, the gas flow rate, the ambient temperature and the wind speed, the oven cavity temperature drops rapidly towards the ambient temperature.

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布基纳法索典型烤炉传热模拟

这项工作涉及在布基纳法索一个典型的烤炉传热的数值研究。数值方法基于节点法，并通过在每个节点上进行热平衡来建立传热方程。然后用隐式有限差分格式对得到的方程进行离散，并用高斯算法求解。实验验证的数值计算结果表明，炉内传热主要受气流、环境温度、火焰熄灭时间和风速的影响。增加气体流量和提高环境温度可以提高炉腔温度。风速的增加导致在运行的前15分钟后，烘箱腔内温度显著下降。当风速超过3m/s时，我们观察到烘箱腔内温度向一个极限值收敛。无论火焰熄灭的时间、气体流速、环境温度和风速如何，烘箱腔内温度都迅速向环境温度下降。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Physical Science International Journal

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