Jie Wang, Zhiqiang Huang, Tao Li, Gang Li, Yuxing Duan, Guoxu Zhang
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A rigid-flexible coupling dynamic model of compressor crankshaft system that considers crosshead pin clearance is established by combining multibody dynamics, collision dynamics, and finite element method. The torsional angular displacement, angular velocity, and force characteristics of the compressor crankshaft system, considering fit clearance and part flexibility, are solved and analyzed. Additionally, the dynamic characteristics of the sliding bearings are determined by considering their clearance, using the finite difference method and the pressure disturbance method. A finite element model of the compressor crankshaft system considering the mixed clearances is constructed. The torsional vibration characteristics of the compressor crankshaft system are compared and analyzed under different fit clearances. The accuracy of the proposed model is validated through compressor on-site operation experiments. The speed error between the experimental and simulated results is found to be only 1.2%. Finally, research on clearance configuration optimization is conducted. The results demonstrate that with a crosshead pin clearance of 0.07 mm and a sliding bearing clearance of 0.1 mm, the angular displacement amplitude of the shafting is reduced by 1.76%, the peak value of rubbing is decreased by 29.49%, and the resonance point of the crankshaft system is minimized. 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引用次数: 0
摘要
页岩气往复式压缩机通常面临工况宽、井多、负荷变化大等问题,这使得压缩机曲轴的扭转振动非常严重。此外,轴瓦运动副之间不可避免地存在配合间隙,这将增加轴瓦的扭转振幅值,放大共振风险。考虑到配合间隙和挠性的影响,本文提出了一种往复式压缩机曲轴系统的扭振计算方法和扭振抑制技术。结合多体动力学、碰撞动力学和有限元法,建立了考虑十字头销间隙的压缩机曲轴系统刚柔耦合动力学模型。在考虑配合间隙和零件柔性的情况下,求解并分析了压缩机曲轴系统的扭转角位移、角速度和力特性。此外,考虑到滑动轴承的间隙,使用有限差分法和压力扰动法确定了滑动轴承的动态特性。考虑到混合间隙,建立了压缩机曲轴系统的有限元模型。比较并分析了不同配合间隙下压缩机曲轴系统的扭转振动特性。通过压缩机现场运行实验验证了所建模型的准确性。实验结果与模拟结果之间的速度误差仅为 1.2%。最后,对间隙配置优化进行了研究。结果表明,在十字头销间隙为 0.07 mm、滑动轴承间隙为 0.1 mm 的情况下,轴系角位移振幅降低了 1.76%,摩擦峰值降低了 29.49%,曲轴系统的共振点最小。这项研究为确保压缩机的稳定可靠运行提供了理论指导。
Torsional vibration characteristics analysis and vibration suppression research of compressor flexible rotor system considering fit clearance
Shale gas reciprocating compressors are usually faced with problems such as wide working conditions, multiple wells, and variable loads, which makes the torsional vibration of the compressor crankshaft serious. In addition, there is an inevitable fit clearance between the moving pairs of the shafting, which will increase the torsional amplitude value of the shafting and amplify the resonance risk. This paper presents a torsional vibration calculation method and a torsional vibration suppression technique for reciprocating compressor crankshaft systems, considering the influence of fit clearance and flexibility. A rigid-flexible coupling dynamic model of compressor crankshaft system that considers crosshead pin clearance is established by combining multibody dynamics, collision dynamics, and finite element method. The torsional angular displacement, angular velocity, and force characteristics of the compressor crankshaft system, considering fit clearance and part flexibility, are solved and analyzed. Additionally, the dynamic characteristics of the sliding bearings are determined by considering their clearance, using the finite difference method and the pressure disturbance method. A finite element model of the compressor crankshaft system considering the mixed clearances is constructed. The torsional vibration characteristics of the compressor crankshaft system are compared and analyzed under different fit clearances. The accuracy of the proposed model is validated through compressor on-site operation experiments. The speed error between the experimental and simulated results is found to be only 1.2%. Finally, research on clearance configuration optimization is conducted. The results demonstrate that with a crosshead pin clearance of 0.07 mm and a sliding bearing clearance of 0.1 mm, the angular displacement amplitude of the shafting is reduced by 1.76%, the peak value of rubbing is decreased by 29.49%, and the resonance point of the crankshaft system is minimized. This research offers theoretical guidance for ensuring the stable and reliable operation of compressors.
期刊介绍:
The journal Multibody System Dynamics treats theoretical and computational methods in rigid and flexible multibody systems, their application, and the experimental procedures used to validate the theoretical foundations.
The research reported addresses computational and experimental aspects and their application to classical and emerging fields in science and technology. Both development and application aspects of multibody dynamics are relevant, in particular in the fields of control, optimization, real-time simulation, parallel computation, workspace and path planning, reliability, and durability. The journal also publishes articles covering application fields such as vehicle dynamics, aerospace technology, robotics and mechatronics, machine dynamics, crashworthiness, biomechanics, artificial intelligence, and system identification if they involve or contribute to the field of Multibody System Dynamics.