Fatigue life prediction of safety valve seal based on orthogonal test

Abstract

In response to the frequent fatigue failure of seals in hydraulic support safety valves under high-pressure, high-flow conditions with water-based media, this study aims to improve the service life of the seal by optimizing its structure. Using ABAQUS and a combined seal fatigue life prediction model, the influence of key structural parameters on fatigue life was investigated. Orthogonal experiments and range analysis were conducted, revealing the order of influence as follows: groove chamfer, relief hole diameter, O-ring compression ratio, and sealing clearance. After optimization, the fatigue life of the seal increased by 2.01 times. The proposed analysis method and model provide a useful reference for the reliability-based design of safety valves in hydraulic supports under high-pressure environments.

Keywords

through-hole seal fatigue life finite-element method orthogonal optimisation

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References

Rivlin

Thomas

. Rupture of rubber. I. Characteristic energy for tearing. J Polym Sci A 1953; 10: 291–318.

Chen

Hia

, et al. Local stress and fatigue lifetime analysis of aircraft rudder actuator. Struct Environ Eng 2014; 41: 57–64.

Liu

Zhao

Shuang

. Fatigue life prediction of natural rubber components using an artificial neural network. Fatigue Fract Eng Mater Struct 2022; 45: 1678–1689.11.019.

Wang

. Prediction method of fatigue life for rubber under multiple-stress. Harbin Institute of Technology, 2016. doi: CNKI:CDMD:2.1016.913377

Pan

Lai

Wang

, et al. Fatigue life prediction and effects of cerium oxide-filled vulcanized natural rubber on fatigue life under multiaxial loading. Fatigue Fract Eng Mater Struct 2021; 44: 3349–3362.

Zhao

, et al. Fatigue life analysis of Ω shape and U shape bellows in mechanical seal. Mech Electr Eng Technol 2023; 52: 163–166.

Cheng

Xiu

, et al. Fatigue analysis of new type screw locking seal structure of high pressure vessel. Petro-Chem Equip 2023; 52: 31–37.

Tobajas

Elduque

Ibarz

, et al. A new multiparameter model for multiaxial fatigue life prediction of rubber materials. Polymers (Basel) 2020; 12: 1195.

Liu

Sun

Zhao

, et al. Numerical study on fatigue life of brush seal based on Miner’s linear cumulative damage theory. Lubr Eng 2023; 48: 48–55.

10.

Xie

Jia

, et al. Research on fatigue failure of vane seal of hydraulic rotary vane actuator. Lubr Eng 2022; 47: 38–44.

11.

Okui

Akihiro

Itsuki

, et al. Prolonging rubber fatigue life using hysteresis of strain-induced crystallization of natural rubber. Polym Test 2023; 117: 107800.

12.

Kim

Nam

Lee

. Evaluation of O-ring stresses subjected to vertical and one side lateral pressure by theoretical approximation comparing with photoelastic experimental results. Eng Fail Anal 2009; 16: 1876–1882.

13.

Liu

Chen

, et al. Comparative analysis on the mechanical properties of O-ring and C-ring built-up seals. Chin J Appl Mech 2021; 38: 306–312.

14.

Zhao

Han

Zhang

, et al. Finite element and fatigue life analysis on polyurethane rubber friction wheel. Comput Aided Eng 2014; 23: 12–15+30.

15.

Shah

QMZ

Chowdhury

Kowser

. Fretting & friction induced fatigue failure: damage criterion of polytetrafluoroethylene. Heliyon 2020; 6.