Your search keyword '"Shi, Xiujiang"' showing total 4 results

1. Optimization Study of Shaft System Vibration and Broken Tooth Fault Under the Influence of 3D Mixed Lubrication of Marine Diesel Engine Timing Gear System

Author

Sun, Wen, Shi, Xiujiang, Lu, Xiqun, Hua, Deliang, Li, Renze, and Liu, He

Published

2024

2. Elastoplastic lubrication analysis of gas turbine bearings.

Author

Feng, Yan, Shi, Xiujiang, Lu, Xiqun, Qiu, Zhuoyi, Sun, Wen, Hua, Deliang, and Li, Renze

Subjects

*GAS-lubricated bearings, *GAS turbines, *ELASTOHYDRODYNAMIC lubrication, *GAS turbine combustion, *GAS analysis, *FAST Fourier transforms, *ELASTOPLASTICITY

Abstract

Bearing of gas turbine often works under bad lubrication conditions. Bearing under heavy load, frequent variable conditions and the instant of gas turbine start and stop will lead to interface lubrication failure and plastic deformation. Taking a typical working condition of a marine gas turbine bearing as an example, aiming at the problem of plastic deformation of gas turbine bearing, the fast Fourier transform method is used to solve the elastic-plastic deformation of bearing, and the elastohydrodynamic lubrication state of gas turbine bearing is numerically calculated. The results show that the plastic deformation will directly affect the lubrication state of gas turbine bearing. Properly increasing the rotating speed will help to form the oil film between the contact surfaces, reduce the maximum residual stress and improve the lubrication state. [ABSTRACT FROM AUTHOR]

Published

2022

3. Three-dimensional mixed lubrication analysis of spur gears with machined roughness.

Author

Shi, Xiujiang, Sun, Wen, Lu, Xiqun, Ma, Xuan, Zhu, Dong, Zhao, Bin, and He, Tao

Subjects

*SPUR gearing, *ELASTOHYDRODYNAMIC lubrication, *LUBRICATION & lubricants, *INTERNAL combustion engines, *HERTZIAN contacts, *STRESS concentration, *3-D films

Abstract

The timing gears of the ship internal combustion engine usually undergo dynamic loading conditions, and often work in a mixed lubrication state. In this study, by considering the three-dimensional (3D) machined roughness, an integrated model with the analysis of mixed lubrication state and dynamic-meshing performance for the spur gear is developed. The model is verified by comparing its results with the predictions using the typical line-contact EHL formulas. The machined roughness apparently affects the local 3D distributions of the film pressure and thickness. The shaved surfaces have the minimum film thickness ratio and the worst lubrication state, while the polished surfaces can improve the lubrication performance of the timing gear pairs greatly. Under the conditions of heavy-load and low-speed, almost all of the Hertzian contact zone appears to be in contact with 0 film thickness, and the local maximum pressure may lead to serious stress concentration, film breakdown, and excessive wear, etc. By optimizing the gear module and pressure angle, the loading capacity of the timing gear is promoted and the contact area gets reduced, the lubrication state improves significantly from mixed lubrication to full film lubrication. • An integrated model with the mixed lubrication and dynamic-meshing performance for the spur gear is developed. • The mixed lubrication model of the timing gear pairs with 3D real roughness is built. • The effects of machined process on mixed lubrication state of the timing gears have been researched. • The ways to improve lubrication by optimizing the gear modulus and pressure angle are investigated. [ABSTRACT FROM AUTHOR]

Published

2019

4. Dynamic characteristics investigation of a dual rotor-casing system considering the comprehensive stiffness of the intermediate bearing.

Author

Liu, Kunpeng, Wang, Donghua, Li, Wanyou, Shi, Xiujiang, and Zhang, Qingchun

Subjects

*BEARINGS (Machinery), *ROLLER bearings, *ROTOR vibration, *HERTZIAN contacts, *ELASTOHYDRODYNAMIC lubrication, *FINITE element method, *DYNAMIC loads, *NONLINEAR systems

Abstract

• A comprehensive stiffness model of intermediate bearing is presented. • A reduced model of dual rotor-bearing-casing coupling system is developed. • The effects of typical parameters on the vibration of the system are discussed. • The mechanism of the comprehensive stiffness and system vibration is revealed. This paper focuses on the vibrational properties of a dual rotor-casing coupled system with nonlinear clearance in the intermediate bearing, considering both the oil film stiffness and Hertzian contact stiffness between rolling elements and raceways. A comprehensive stiffness model for the intermediate bearing has been developed based on elastohydrodynamic lubrication (EHL) and Hertz contact theory. Subsequently, a dynamical model of the dual rotor-bearing-casing system is established using the finite element method, thereby verifying the feasibility of simulating the casing with beam elements. The dimensionality of the system equation is reduced using the fixed-interface component mode synthesis (CMS) method, and the resulting reduced-dimensionality equation is solved using the improved Newmark- β method. The effects of casing support, rotational speed, and radial clearance on the vibration characteristics of the system are investigated. Then, the comprehensive stiffness and coupled vibration characteristics of the system are analyzed to elucidate its intrinsic mechanism. Finally, the contact characteristics within the intermediate bearing under dynamic load are also studied. The results indicate that the support stiffness of the casing has a more significant impact on the second resonance caused by both the inner and outer rotors. The system is prone to experiencing varying compliance (VC) resonance at low rotational speeds. The excessive bearing clearance leads to complex vibrational characteristics of the system, making it challenging to predict its motion. The impact of minor changes in stiffness on system vibration is small when the comprehensive stiffness is large. At this time, the limited effect of oil film stiffness allows it to be disregarded in terms of comprehensive stiffness. Furthermore, the speed significantly influences the contact characteristics within the intermediate bearing under the unbalanced force of the rotor and gravity. [ABSTRACT FROM AUTHOR]

Published

2024