机械工程学报 ›› 2026, Vol. 62 ›› Issue (9): 104-130.doi: 10.3901/JME.260306
• 机械动力学 • 上一篇
张颖1, 魏士杰2, 姜鹏飞1, 王中阳1, 武通海1, 雷亚国1, 曹军义1
收稿日期:2025-05-19
修回日期:2025-12-11
发布日期:2026-07-08
作者简介:张颖,男,1995年出生,博士,助理教授。主要研究方向为非线性振动控制。E-mail:yingzhang@xjtu.edu.cn;曹军义(通信作者),男,1977年出生,博士,教授,博士研究生导师。主要研究方向为振动噪声分析与控制、智能材料与结构。E-mail:caojy@mail.xjtu.edu.cn
基金资助:ZHANG Ying1, WEI Shijie2, JIANG Pengfei1, WANG Zhongyang1, WU Tonghai1, LEI Yaguo1, CAO Junyi1
Received:2025-05-19
Revised:2025-12-11
Published:2026-07-08
摘要: 燃油齿轮泵作为供油系统的核心部件,凭借其结构紧凑、效率优异及成本低廉等优势,在高端装备领域得以广泛应用。然而,齿轮啮合、流量脉动、润滑状态及壳体共振等因素诱发的振动问题,显著降低了燃油齿轮泵的工作性能,限制了其在高压力、高转速及大排量工况下的应用潜力。为此,深入探究燃油齿轮泵的振动产生机理与传递特性,进而有效抑制泵体振动已成为该领域亟待解决的关键问题。为推动燃油齿轮泵减振技术的创新发展,全面综述了燃油齿轮泵振动动力学机理与减振技术的研究进展。首先,从内部振动激励源的角度,系统地阐述了齿轮泵转子系统的多物理场耦合动力学建模方法,考虑了齿轮时变啮合刚度、流体压力脉动和滑动轴承润滑状态等因素。其次,从振动传递路径角度,详细评述了燃油齿轮泵基于外部激励的实验模态分析技术与基于工况数据的运行模态分析技术。基于此,系统总结了壳体结构优化、齿轮齿廓修形、卸荷槽设计及多级齿轮泵等减振技术的研究进展。最后,深入探讨了燃油齿轮泵减振技术面临的核心挑战与未来发展机遇,为提升燃油齿轮泵的供油品质和服役寿命提供了理论指导和研究方向。
中图分类号:
张颖, 魏士杰, 姜鹏飞, 王中阳, 武通海, 雷亚国, 曹军义. 燃油齿轮泵振动的动力学机理与减振技术研究进展及挑战[J]. 机械工程学报, 2026, 62(9): 104-130.
ZHANG Ying, WEI Shijie, JIANG Pengfei, WANG Zhongyang, WU Tonghai, LEI Yaguo, CAO Junyi. Research Status and Challenges on Vibration Dynamic Mechanism and Control Technology for Fuel Gear Pumps[J]. Journal of Mechanical Engineering, 2026, 62(9): 104-130.
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