Xinbo Qian, Chengchang Wu, Yilai Liu, and Changjin Wang


  1. [1] International Organization for Standardization, Hydraulic fluidpower – Fatigue pressure testing of metal pressure-containingenvelopes – Part 1: Test method. ISO 10771-1:2015.
  2. [2] J.L. Dong, Analysis and repair of bursting of the pressure-bearing shell of the first waste heat boiler, Large ScaleNitrogenous Fertilizer Industry, 24(4), 2001, 253–255.
  3. [3] W.H. Chen, Q.C. He, J. Pan, P. Qian, and L.Q. Zhong,Reliability test technology of mechanical products – Overviewand prospect, China Mechanical Engineering, 31(1), 2020,72–82.
  4. [4] C.X. Zheng, L. Wang, R. Li, Z.X. Wei, and S. Wei, Shuttlecarbon fiber composite pressure fuselage shell hydraulic fatiguetesting system, ZL201310305467.2, Aug. 26, 2015.
  5. [5] S. Luo and W.B. Wang, Status and prospects on the pressureshell structure of submersible, Ship Science and Technology,41(10), 2019, 7–16.
  6. [6] H.Z. Wu, D.P. Gao, and H.D. Guo, Generalization of lifecharacteristic investigation for probabilistic fatigue failure,Structure & Environment Engineering, 17(4), 2002, 18–22.
  7. [7] X.L. Wang, Study on Uncertain Fatigue Life Prediction Method,Nanjing University of Aeronautics and Astronautics, Nanjing,China, 2009.
  8. [8] J. Zhou, B.S. Xu, H.D. Wang, Z.G. Xing, and J.J. Kang,Application and development of finite element method infatigue analysis, Physical Testing and Chemical Analysis (PartA: Physical Testing), 49(10), 2013, 674–676.
  9. [9] L.M. Shkolnik, Manual of fatigue test methods. (Beijing:Machinery Industry Press, 1983).
  10. [10] G.W. He and H.B. Xu, Reliability test technology. (Beijing:National Defense Industry Press, 1995), 2–6.
  11. [11] S.J. Skaistis and D.L. Xu, Select hydraulic components basedon fatigue strength, Chinese Hydraulics and Pneumatics, (3),1979, 63–66.187
  12. [12] American Petroleum Institute, Pressure Vessel InspectionCode: In-service Inspection, Rating, Repair, and Alteration,API 510, Washington, DC, 2014.
  13. [13] American Petroleum Institute, Piping Inspection Code:Inspection, Repair, Alteration, and Rerating of In-servicePiping Systems, API 570, Washington, DC, 2016.
  14. [14] C.W. Payne, J.S. Warneke, and J.T. Kaculi, Liner hangerrating methodologies validated with physical testing, Proc.Offshore Technology Conf., Houston, TX, May 2016, 2–5.
  15. [15] G.S. Wasserman and D. Marcel, Reliability verification testing,and analysis in engineering design, (New York, NY: QualityProgress, 2003), 212–260.
  16. [16] X.M. Tang, Analysis and Evaluation of Small Samples Test ofWeapon Equipment. (Beijing: National Defense Industry Press,2001).
  17. [17] X. Chen and C.H. Zhang, Research application anddevelopment of accelerated testing, Journal of MechanicalEngineering, 45(8), 2009, 130–136.
  18. [18] G. Yang, Life cycle reliability engineering. (Hoboken, NJ:Wiley, 2007), 334–351.
  19. [19] L. Luo, J. Hamilton, Z. Wei, and R. Rebandt, Fatigue andfracture test planning, test data acquisitions and analysis.(West Conshohocken, PA: ASTM International, 2017).
  20. [20] G. Yang, Reliability demonstration through degradationbogey testing, IEEE Transactions on Reliability, 58(4), 2009,604–610.
  21. [21] W. Luo, Research on Theory and Method of ReliabilityDemonstration Based on Accelerated Test, National Universityof Defense Technology, Changsha, China, 2013, 43–66.
  22. [22] A.F. Shahraki, O.P. Yadav, and H. Liao, A review ondegradation modelling and its engineering applications,International Journal of Performability Engineering, 13(3),2017, 299–314.
  23. [23] S.H. Hao, J. Yang, and C. Berenguer, Nonlinear step-stressaccelerated degradation modelling considering three sources ofvariability, Reliability Engineering & System Safety, 172(Apr.),2018, 207–215.
  24. [24] Y.S. Wang, C.H. Zhang, S.F. Zhang, X. Chen, and Y.Y. Tan,Optimal design of constant stress accelerated degradation testplan with multiple stresses and multiple degradation measures,Proceedings of the Institution of Mechanical Engineers, PartO: Journal of Risk and Reliability, 229(1), 2015, 83–93.
  25. [25] H. Wang, Y. Zhao, X.B. Ma, and H.Y. Wang, Optimal designof constant-stress accelerated degradation tests using the M-optimality criterion, Reliability Engineering & System Safety,164(Aug.), 2017, 45–54.
  26. [26] National Fluid Power Association, Fluid power components –Method for verifying the fatigue and establishing the burstpressure ratings of the pressure containing envelope of a metalfluid power component, NFPA/T2.6.1 R2-2001 (R2014), 2014.
  27. [27] International Organization for Standardization. Hydraulic fluidpower – Fatigue pressure testing of metal pressure-containingenvelopes – Part 2: Rating methods, ISO/TR 10771-2:2008.
  28. [28] P.L. Du and Q.J. Li, Determination of the rated fatigue strengthof the pressure chamber of GH125/70 hydraulic cylinder,Mechanical Strength, 14(3), 1992, 5.
  29. [29] The State Administration for Market Regulation and theNational Standardization Administration of China, Methodsto assess the reliability of hydraulic components, GB/T 35023-2018.
  30. [30] X.X. Shi, X.D. Zhu, and J. Zhang, Simulation and experimentalanalysis of drive motor stator current under local fault of gear,Mechatronic Systems and Control, 49(2), 2021, 74–82.
  31. [31] J.S. Si, Y. Cao, and X.J. Shi, Fault diagnosis of wind turbineplanetary gearbox based on HHT and structure resonancedemodulation, Mechatronic Systems and Control, 47(1), 2019,36–42.
  32. [32] B.B. Li, J.L. Zhao, B. Liu, and F. Xu, Numerical simulation andbehaviour analysis of a 3D 6-DOF seismic simulation shakingtable system, Mechatronic Systems and Control, 50(1), 2022,9–15.
  33. [33] J. Ducr´ee, Systematic review of centrifugal valving based ondigital twin modeling towards highly integrated lab-on-a-discsystems, Microsystems & Nanoengineering, 104(7), 2021, 1–26.

Important Links:

Go Back