Coupling analysis of cylinder block for two-stroke aviation piston engine

IF 2.2 4区工程技术 Q2 ENGINEERING, MECHANICAL

International Journal of Engine Research Pub Date : 2024-04-16 DOI:10.1177/14680874241246894

Zhongjian Pan, Qinghua He, Yi Li, Lei Guo

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Abstract

The aluminum alloy block is a component of aircraft piston engine, and it is prone to fatigue cracks when working in a thermal mechanical coupling state for a long time. Establish a GT-POWER simulation model for a certain type of engine, verify the accuracy of the model, obtain boundary parameters such as temperature and pressure of the engine block under harsh operating conditions through the model, and divide the cylinder wall into gradients based on the engine operating conditions to obtain the surface heat transfer coefficient of the block, and then obtain the temperature field distribution of the engine body. The coupling analysis of the cylinder burst pressure and temperature field of the engine block under harsh working conditions showed that the maximum stress of the engine block was 292.55 MPa and the maximum deformation was 0.39 mm, with thermal load being the main factor causing deformation. Conduct a complete engine bench test, and under the 1000 h bench durability test, there are no cracks on the engine block, indicating that the design and analysis meet the requirements.

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二冲程航空活塞发动机气缸体的耦合分析

铝合金缸体是航空活塞发动机的部件，长期处于热机械耦合状态下工作，容易产生疲劳裂纹。建立某型发动机的 GT-POWER 仿真模型，验证模型的准确性，通过模型得到发动机缸体在恶劣工况下的温度、压力等边界参数，并根据发动机工况将缸壁划分梯度，得到缸体的表面传热系数，进而得到发动机机体的温度场分布。对恶劣工况下发动机缸体的爆缸压力和温度场进行耦合分析，结果表明发动机缸体的最大应力为 292.55 MPa，最大变形量为 0.39 mm，其中热负荷是导致变形的主要因素。进行发动机整机台架试验，在 1000 h 的台架耐久试验下，发动机缸体没有出现裂纹，说明设计和分析符合要求。

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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