Investigation of Gas Turbine Blade Materials for Efficient Energy System

Journal of Technology Innovations and Energy Pub Date : 2023-11-29 DOI:10.56556/jtie.v2i4.680

Irfan Ullah, Najma Bashir

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Abstract

The present study aims to determine the best and most economical material for a gas turbine blade, which operates under high-temperature conditions and experiences high static structural and thermal loads. To achieve this objective, three different types of material alloys, namely Titanium alloy Ti6AL4V, Magnesium alloy AZ80, and Aluminum alloy 7075-T6, were selected for comparison. A turbine blade model was designed using Solid Works software, and structural and thermal analyses were performed using ANYAS 15.0 under steady-state conditions. The structural analysis aimed to determine the stress, strain, and deformation results on turbine blades by applying high pressure, while the thermal analysis aimed to determine the temperature distribution influences and heat flux generation by applying high temperatures. Based on the results obtained from both analyses of the three different materials, Titanium alloy Ti6AL4V is the best and most economical material. This material showed low stress, strain, and little deformation and the best material properties at high temperatures when compared to Magnesium alloy AZ80 and Aluminum alloy 7075-T6.

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高效能源系统燃气轮机叶片材料研究

本研究旨在确定在高温条件下运行并承受高静态结构和热负荷的燃气轮机叶片的最佳和最经济材料。为实现这一目标，我们选择了三种不同类型的合金材料，即钛合金 Ti6AL4V、镁合金 AZ80 和铝合金 7075-T6 进行比较。使用 Solid Works 软件设计了涡轮叶片模型，并使用 ANYAS 15.0 进行了稳态条件下的结构和热分析。结构分析旨在确定高压作用下涡轮叶片的应力、应变和变形结果，而热分析旨在确定高温作用下的温度分布影响和热通量产生。根据对三种不同材料的分析结果，钛合金 Ti6AL4V 是最好、最经济的材料。与镁合金 AZ80 和铝合金 7075-T6 相比，这种材料应力小、应变小、变形小，在高温下具有最好的材料特性。

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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Journal of Technology Innovations and Energy

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