Engine performance enhancement by improving heat transfer in between exhaust valve and valve seat through CFD (transient thermal) simulation

Pub Date : 2021-05-03 DOI:10.1063/5.0048421

M. Hassan, A. Shahriman, Z. Razlan, N. S. Kamarrudin, I. Aziz, W. Khairunizam, M. Hashim, A. Harun, I. Ibrahim, Zunaidi Ibrahim, M. Faizi, M. Rani, R. Murali

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引用次数: 2

Abstract

The combustion of the internal combustion engine results in high heat and pressure produce as exhaust gas. The high-temperature exhaust gas will transfer the heat to surrounding via convection, conduction, and radiation. In the combustion chamber, the exhaust valve and its seat will reach high temperatures due to hot gases exit through the engine exhaust port. This high temperature must be reduced to avoid damaging the engine. In this project, the existing material of the valve seat is tested using computational fluid dynamics simulation for heat analysis. Simulation of transient thermal is conducted to study the detailed behavior of heat transfer of the valve and valve seat in the engine. Four copper-based material of the valve seat is selected which is beryllium copper, chromium copper, brass, bronze are simulated. In the simulation, the brass valve seat has the highest heat absorbance rate which averagely 30% higher than cast iron valve seat in terms of temperature differences. Most of the copper-based valve seat can absorb averagely 10% to 30% more heat than cast iron valve seat depends on the material’s thermal conductivity.

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通过CFD(瞬态热)模拟改善排气阀与气门座之间的传热，提高发动机性能

内燃机的燃烧产生高热量和高压作为废气。高温废气通过对流、传导、辐射等方式将热量传递给周围环境。在燃烧室中，由于热气通过发动机排气口排出，排气阀及其阀座将达到高温。这种高温必须降低，以免损坏发动机。在本项目中，对现有的阀座材料进行了测试，采用计算流体动力学模拟进行热分析。为研究发动机气门及气门座的传热特性，进行了瞬态热仿真。阀座选用的四种铜基材料分别是铍铜、铬铜、黄铜、青铜。在模拟中，黄铜阀座的吸热率最高，在温差方面比铸铁阀座平均高30%。根据材料的导热性，大多数铜基阀座比铸铁阀座平均多吸收10%至30%的热量。

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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