应用于航空活塞发动机的快速响应涡轮增压器气动-热力-机械综合设计方法

IF 5.4 2区 工程技术 Q1 ENGINEERING, AEROSPACE
Yu Zhou , Yue Song , Shuai Zhao , Xueyu Li , Longtao Shao , Huansong Yan , Zheng Xu , Shuiting Ding
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引用次数: 0

摘要

受限于涡轮增压器较差的瞬态响应性能,航空活塞发动机的动态性能趋于恶化。为了提高涡轮增压器的加速能力,本研究仔细研究了影响其性能的各种因素。根据涡轮增压器的工作原理和瞬态响应过程,确定了三种惯性,即空气动力惯性(ADI)、热惯性(TI)和机械惯性(MI),并针对这三种惯性进行了设计。首先,本文开创性地定义了评估涡轮增压器瞬态响应性能的方法。受 MI 定义的启发,该方法引入了 ADI 参数。随后,引入了具有低 Biot 数的薄壁涡流设计和轻质涡轮叶轮,以降低涡轮增压器的 TI 和 MI。涡道和扩散器内流场分布的模拟结果表明,综合设计方法能有效改善这些部件内的气体压力和温度分布。值得注意的是,恒定力矩涡道(CMV)的压力分布波动比恒定速度力矩涡道(CVMV)低 62.8%。低 TI 薄壁涡道不仅提高了涡轮增压器的响应速度,还将其重量减轻了约 40%。三种惯性对发动机响应速度的影响量化如下:ADI(94%);MI(5%);TI(1%)。涡轮增压器和发动机的测试结果验证了这一结论。这种设计方法不仅大大提高了涡轮增压器的响应性能,还为其他叶片机械系统的优化设计提供了宝贵的启示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A comprehensive aerodynamic-thermal-mechanical design method for fast response turbocharger applied in aviation piston engines

Limited by the poor transient response performance of turbochargers, the dynamic performance of aviation piston engines tends to deteriorate. In a bid to enhance the turbocharger's acceleration capabilities, this study scrutinizes various factors impacting its performance. Based on the operational principles and transient response process of the turbocharger, three types of inertia—namely, aerodynamic inertia (ADI), thermal inertia (TI), and mechanical inertia (MI) — are identified and addressed for design. To begin, this paper pioneers the innovative definition of a method for evaluating the transient response performance of the turbocharger. This method incorporates the introduction of an ADI parameter, inspired by the definition of MI. Subsequently, a thin-walled volute design with a low Biot number and a lightweight turbine impeller is introduced to reduce the turbocharger's TI and MI. The simulation results of the flow field distribution within the volute and diffuser demonstrate the comprehensive design method's effectiveness in improving gas pressure and temperature distributions in these components. Notably, the pressure distribution fluctuation in the constant moment-of-momentum volute (CMV) is 62.8% lower than that in the constant velocity moment volute (CVMV). The low-TI thin-walled volute not only enhances the turbocharger's response speed but also reduces its weight by approximately 40%. The impact of three types of inertia on the engine's response speed is quantified as follows: ADI (94%) > MI (5%) > TI (1%). This conclusion has been verified through test results of both the turbocharger and the engine. This design method not only significantly improves the turbocharger's response performance but also offers valuable insights for the optimal design of other blade mechanical systems.

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来源期刊
CiteScore
7.50
自引率
5.70%
发文量
30
期刊介绍: Propulsion and Power Research is a peer reviewed scientific journal in English established in 2012. The Journals publishes high quality original research articles and general reviews in fundamental research aspects of aeronautics/astronautics propulsion and power engineering, including, but not limited to, system, fluid mechanics, heat transfer, combustion, vibration and acoustics, solid mechanics and dynamics, control and so on. The journal serves as a platform for academic exchange by experts, scholars and researchers in these fields.
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