Performance reliability evaluation of high‐pressure internal gear pump

IF 2.2 3区 工程技术 Q3 ENGINEERING, INDUSTRIAL Quality and Reliability Engineering International Pub Date : 2024-05-28 DOI:10.1002/qre.3585
Yu Tang, Hao Lu, Zhencai Zhu, Zhiyuan Shi, Beilian Xu
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Abstract

With the development of the high‐end equipment technology, the performance requirements of the internal gear pump (IGP) under high pressure are also increasing. However, the increase of working pressure will lead to the instability of gear pump performance in terms of volumetric efficiency, noise, reliability and so on, it is necessary to reasonably evaluate the reliability level of high‐pressure IGP. The reliability analysis of the high‐pressure IGP is carried out from the aspects of flow, noise, and gear strength in this paper. First, the output flow rate and far‐field flow‐induced noise of the high‐pressure IGP were obtained through fluid numerical simulation, and experimental verification was conducted. Then, based on the time‐varying meshing stiffness, backlash function and static transmission error of the gear pair, a nonlinear dynamic model of the internal meshing gear pair was established. The time‐varying meshing force was obtained through the dynamic model of the gear pair, and then the tooth contact stress and tooth root bending stress were obtained. Finally, considering the uncertain factors affecting the performance of the high‐pressure IGP, Latin hypercube sampling (LHS) combined with dendrite network (DD) was used for random response modeling. The performance reliability of the high‐pressure IGP, including output flow rate, far‐field flow‐induced noise, and the strength of gear pair, were estimated based on the fourth moment‐based saddlepoint approximation (FMSA). The reliability analysis results can provide a theoretical basis for the structural optimization design of the high‐pressure IGP.
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高压内啮合齿轮泵的性能可靠性评估
随着高端装备技术的发展,对内啮合齿轮泵(IGP)在高压下的性能要求也越来越高。然而,工作压力的增加会导致齿轮泵在容积效率、噪声、可靠性等方面的性能不稳定,因此有必要对高压内啮合齿轮泵的可靠性水平进行合理评估。本文从流量、噪声、齿轮强度等方面对高压 IGP 进行了可靠性分析。首先,通过流体数值模拟得到了高压 IGP 的输出流量和远场流致噪声,并进行了实验验证。然后,根据齿轮副的时变啮合刚度、反向间隙函数和静态传动误差,建立了内啮合齿轮副的非线性动态模型。通过齿轮副的动态模型得到了时变啮合力,进而得到了齿接触应力和齿根弯曲应力。最后,考虑到影响高压内啮合齿轮性能的不确定因素,采用拉丁超立方采样(LHS)结合树枝状网络(DD)进行随机响应建模。基于第四矩鞍点近似(FMSA)估算了高压 IGP 的性能可靠性,包括输出流量、远场流诱导噪声和齿轮副强度。可靠性分析结果可为高压 IGP 的结构优化设计提供理论依据。
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来源期刊
CiteScore
4.90
自引率
21.70%
发文量
181
审稿时长
6 months
期刊介绍: Quality and Reliability Engineering International is a journal devoted to practical engineering aspects of quality and reliability. A refereed technical journal published eight times per year, it covers the development and practical application of existing theoretical methods, research and industrial practices. Articles in the journal will be concerned with case studies, tutorial-type reviews and also with applications of new or well-known theory to the solution of actual quality and reliability problems in engineering. Papers describing the use of mathematical and statistical tools to solve real life industrial problems are encouraged, provided that the emphasis is placed on practical applications and demonstrated case studies. The scope of the journal is intended to include components, physics of failure, equipment and systems from the fields of electronic, electrical, mechanical and systems engineering. The areas of communications, aerospace, automotive, railways, shipboard equipment, control engineering and consumer products are all covered by the journal. Quality and reliability of hardware as well as software are covered. Papers on software engineering and its impact on product quality and reliability are encouraged. The journal will also cover the management of quality and reliability in the engineering industry. Special issues on a variety of key topics are published every year and contribute to the enhancement of Quality and Reliability Engineering International as a major reference in its field.
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