Simulation studies on combined effect of variable geometry, rotation and temperature gradient on critical speed of gas turbine disc

IF 1.7 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Multidiscipline Modeling in Materials and Structures Pub Date : 2023-01-25 DOI:10.1108/mmms-07-2022-0139
Ranjan Kumar, S. Chaterjee, V. Ranjan, S. Ghoshal
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Abstract

PurposeThe present findings report a significant influence of disc profile and thickness on the order of excitation leading to critical speed condition. Certain transverse modes of vibration of the disc have been obtained to be more susceptible to get excited while recording the lowest critical speeds.Design/methodology/approachNumerical simulation using finite-element method has been adopted due to the complicated geometry, complex loadings and intricate analytical formulation. A comprehensive analysis of exclusive as well as combination of thermal and centrifugal loads has been taken up to determine the intensity and characteristics of the individual/combined effects.FindingsThe typical gas turbine disc profile has been analyzed to predict the critical speed under the factual working condition of an aero-engine. FEM analysis of uniform and variable thickness discs have been carried out under stationary, rotating and rotating-thermal considerations while emphasizing the effect of disc profile and thickness. Centrifugal stresses developed due to rotational effect result in unceasing stiffening of the discs with higher stiffening for a greater number of nodal diameters. On the other hand, a role reversal of thermal effect from stiffening to softening is figured out with increasing numbers of nodal diameters. However, the discs are subjected to an overall stiffening effect on account of the combined centrifugal and thermal loading, with the effect decreasing with an increase in disc thickness. Under the combined loading, the order of excitation leading to critical speed condition is dependent on disc profile and thickness. Moreover, the vibrational modes (0,1) and (0,2) are identified as more prominent adverse modes corresponding to lowest critical speeds.Practical implicationsThe present findings are expected to serve as guidelines during the design phase of gas turbine discs of aeroengine applications.Originality/valueThe present work deliberates on the simulation and analysis of gas turbine disc specific to aeroengine application. The real-life disc geometry has been analyzed with due consideration of major factual operating conditions to identify the critical speed. The identification of various critical speed using numerical analysis can help to reduce the number of experimental tests required for certification.
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变几何、旋转和温度梯度对燃气轮机盘临界转速联合影响的仿真研究
目的本研究报告了圆盘轮廓和厚度对导致临界转速条件的激励顺序的显著影响。在记录最低临界速度时,圆盘的某些横向振动模态更容易被激发。设计/方法/途径由于结构复杂、载荷复杂、解析公式复杂,采用了有限元数值模拟方法。为了确定单个/组合效应的强度和特征,对热载荷和离心载荷的单独和组合进行了综合分析。结果分析了某型航空发动机实际工况下典型燃气轮机盘型的临界转速。在强调盘型和盘厚影响的情况下,对均匀和变厚盘进行了静、转、转热三种工况下的有限元分析。由于旋转效应而产生的离心应力导致圆盘不断硬化,对于更多的节点直径,硬化程度更高。另一方面,随着节点直径的增加,热效应从硬化到软化的作用发生了逆转。然而,由于离心和热载荷的联合作用,圆盘受到整体加筋效应,随着圆盘厚度的增加,这种效应减小。在组合载荷下,导致临界转速的激励顺序取决于盘形和盘厚。此外,振动模态(0,1)和(0,2)被识别为与最低临界速度相对应的更突出的不利模态。实际意义本研究结果有望为航空发动机燃气涡轮盘的设计阶段提供指导。本文对航空发动机专用燃气涡轮盘的仿真与分析进行了研究。对实际工况下的阀瓣几何形状进行了分析,并充分考虑了主要实际工况,以确定临界转速。使用数值分析确定各种临界速度有助于减少认证所需的实验测试次数。
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来源期刊
CiteScore
3.70
自引率
5.00%
发文量
60
期刊介绍: Multidiscipline Modeling in Materials and Structures is published by Emerald Group Publishing Limited from 2010
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