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Due to their excellent performance, composite materials are increasingly used in the marine field. It is of great importance to study the low-velocity impact performance of composite laminates to ensure the operational safety of composite ship structures. Herein, low-velocity drop-weight impact tests were carried out on 12 types of GRP laminates with different layup forms. The impact-induced mechanical response characteristics of the GRP laminates were obtained. Based on the damage model and stiffness degradation criterion of the composite laminates, a low-velocity impact simulation model was proposed by writing a VUMAT subroutine and using the 3D Hashin failure criterion and the cohesive zone model. The fibre failure, matrix failure and interlaminar failure of the composite structures could be determined by this model. The predicted mechanical behaviours of the composite laminates with different layup forms were verified through comparisons with the impact test results, which revealed that the simulation model can well characterise the low-velocity impact process of the composite laminates. According to the damage morphologies of the impact and back sides, the influence of the different layup forms on the low-velocity impact damage of the GRP laminates was summarised. The layup form had great effects on the damage of the composite laminates. Especially, the outer 2‒3 layers play a major role in the damage of the impact and the back side. For the same impact energy, the damage areas are larger for the back side than for the impact side, and there is a corresponding layup form to minimise the damage area. Through analyses of the time response relationships of impact force, impactor displacement, rebound velocity and absorbed energy, a better layup form of GRP laminates was obtained. Among the 12 plates, the maximum impact force, absorbed energy and damage area of the plate P4 are the smallest, and it has better impact resistance than the others, and can be more in line with the requirements of composite ships. It is beneficial to study the low-velocity impact performance of composite ship structures.
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Czasopismo
Rocznik
Tom
Strony
59--71
Opis fizyczny
Bibliogr. 38 poz., rys., tab.
Twórcy
autor
- imei University, School of Marine Engineering, No.176, Shigu Road, 361021 Xiamen, Fujian Provincial Key Laboratory for Naval Architecture and Ocean Engineering China
autor
- Jimei University, School of Marine Engineering, No.176, Shigu Road, 361021 Xiamen, Fujian Provincial Key Laboratory for Naval Architecture and Ocean Engineering China
autor
- Jimei University, School of Marine Engineering, No.176, Shigu Road, 361021 Xiamen, Fujian Provincial Key Laboratory for Naval Architecture and Ocean Engineering China
autor
- Jimei University, School of Marine Engineering, No.176, Shigu Road, 361021 Xiamen, Fujian Provincial Key Laboratory for Naval Architecture and Ocean Engineering China
autor
- Jimei University, School of Marine Engineering, No.176, Shigu Road, 361021 Xiamen, Fujian Provincial Key Laboratory for Naval Architecture and Ocean Engineering China
Bibliografia
- 1. Li X., Zhu Z., Li Y., Hu Z. (2020): Design and mechanical analysis of a composite t-type connection structure for marine structures. Polish Maritime Research, 2020, 27(2): 145-157.
- 2. Tomasz F., Tomasz M. (2020):Validation process for computational model of full-scale segment for design of composite footbridge. Polish Maritime Research, 27(2): 158-167.
- 3. Li X., Zhu Z., Li Y., Hu Z., Dai L. (2020): A review on ultimate strength of composite-metal hybrid ships. Journal of Ship Mechanics, 24(05): 681-692.
- 4. Niksa-Rynkiewicz T., Landowski M., Szalewski P. (2020): Application of apriori algorithm in the lamination process in yacht production. Polish Maritime Research, 27(3): 59-70.
- 5. Qiu A., Fu K., Zhao C., et al. (2013): Numerical understanding the impact behaviors of marine composite laminates. 1st International Conference on Advanced Composites for Marine Engineering. 2013.
- 6. Thorsson S. I., Waas A. M., Rassaian M. (2018): Numerical investigation of composite laminates subject to low-velocity edge-on impact and compression after impact. Composite Structures, 203.
- 7. Liao B., Zhou J., Lin Y., et al. (2019): Low-velocity impact behavior and damage characteristics of CFRP laminates. Chinese Journal of High Pressure Physics, 33(04): 105-113.
- 8. Oliveira Ferreira G. F., et al. (2019): Computational analyses of composite plates under low-velocity impact loading. Materials Today: Proceedings, 2019, 8.
- 9. Thorsson S. I., Waas A M., Rassaian M. (2018): Lowvelocity impact predictions of composite laminates using a continuum shell based modeling approach part A: Impact study. International Journal of Solids and Structures, 155: 185-200.
- 10. Panettieri E., Fanteria D., Montemurro M., Froustey C. (2016): Low-velocity impact tests on carbon/epoxy composite laminates: A benchmark study. Composites Part B, 107: 9-21.
- 11. Shi Y., Pinna C., Soutis C. (2014): Modelling impact damage in composite laminates: A simulation of intra- and interlaminar cracking. Composite Structures, 114.
- 12. Xu Y., Zuo H., Lu X., et al. (2019): Numerical analysis and tests for low-velocity impact damage evaluation of composite material. Journal of Vibration and Shock, 38(03): 149-155.
- 13. Gliszczynski A., et al. (2019): Barely visible impact damages of GFRP laminate profiles ‒ An experimental study. Composites Part B: Engineering, 158: 10-17.
- 14. Gliszczynski A. (2018): Numerical and experimental investigations of the low velocity impact in GFRP plates. Composites Part B Engineering, 138: 181-193.
- 15. Moura M. D., Marques A. T. (2002): Prediction of low velocity impact damage in carbon-epoxy laminates. Composite: Part A, 33: 361-368.
- 16. Moura M. D., Goncalves J. P. (2004): Modelling the interaction between matrix cracking and delamination in carbon-epoxy laminates under low velocity impact. Composites Science and Technology, 64: 1021-1027.
- 17. Hou J. P., Petrinic N., Ruiz C., Hallett S. R. (2000): Prediction of impact damage in composite plates. Composite Science and Technology, 60: 273-281.
- 18. Luo R. K. (2000): The evaluation of impact damage in a composite plate with a hole[J]. Composite Science and Technology, 60: 49-58.
- 19. Wen W., Xu Y., Cui H. (2007): Damage analysis of laminated composites under low velocity impact loading. Journal of Materials Engineering, 7: 6-11.
- 20. Zhu W. (2012): Research on residual strength and fatigue performance of composite laminates with low-velocity impact damage. Dissertation, Nanjing: Nanjing University of Aeronautics and Astronautics.
- 21. Zhu D., Zhang W., et al. (2014): Studies of several influence factors of low-velocity impact damaged characterization on composite laminates. Ship Science and Technology, 11: 57-65.
- 22. Dong H., An X., et al. (2015): Progress in research on low velocity impact properties of fibre reinforced polymer matrix composite. Journal of Materials Engineering, 43(5): 89-100.
- 23. Zu Z. (2020): Experimental investigation on repeated low velocity impact damage and residual compressive strength of honeycomb sandwich panel. Dissertation, Shandong: Shandong University of Technology.
- 24. Guden M., Yildirim U., Hall I. W. (2004): Effect of strain rate on the compression behavior of a woven glass fiber/ SC-15 composite. Polymer Testing, 23(6): 719-725.
- 25. Hosur M., Alexander J., Vaidya U., et al. (2004): Studies on the off-axis high strain rate compression loading composites. Composite Structures, 63(1): 75-85.
- 26. Hashin Z., Rotem A. (1973): A fatigue failure criterion for fiber reinforced materials. Journal of Composite Materials, 7(4): 448-464.
- 27. Hashin Z. (1980): Failure criteria for unidirectional fiber composites. Journal of Applied Mechanics, 47(2): 329-334.
- 28. Ferreira R. T. L., Ashcroft I. A. (2020): Optimal orientation of fibre composites for strength based on Hashin’s criteria optimality conditions. Structural and Multidisciplinary Optimization, 61: 2155-2176.
- 29. Chaht F. L., Mokhtari M., Benzaama H. (2019): Using a Hashin Criteria to predict the damage of composite notched plate under traction and torsion behavior. Fracture and Structural Integrity, 13(50): 331-341.
- 30. Ha W. (2018): Study on failure modes and residual strength of composite laminates under low-velocity impact. Dissertation, Harbin: Harbin Institute of Technology.
- 31. Yang Y., Liu X., Wang Y. Q., et al. (2017): A progressive damage model for predicting damage evolution of laminated composites subjected to three-point bending. Composites Science and Technology, 151.
- 32. Sun X. (2018): Numerical simulation of gradual damage on bolt-bonded hole composite laminates. Dissertation, Harbin: Harbin Engineering University.
- 33. Shi J. (2015): The finite element analysis of the progressive damage of composite laminated plates based on ABAQUS. Dissertation, Shanxi: North University of China.
- 34. Abir M. R., Tay T. E., Ridha M., Lee H. P. (2017): Modelling damage growth in composites subjected to impact and compression after impact. Composite Structures, 168: 13-25.
- 35. Benzeggagh M. L., Kenane M. (1996): Measurement of mixed-mode delamination fracture toughness of unidirectional glass/epoxy composites with mixed-mode bending apparatus. Composites Science and Technology, 56(4): 439-449.
- 36. Chen Y., Yu Z., Wang H. (2012): Numerical modeling of scale effects on the responses of laminated composite plate under low velocity impact. Chinese Journal of Solid Mechanics, 33(6): 574-582.
- 37. Liu H. (2006): Numerical simulation of delamination damage in composite materials. Dissertation, Shanxi: Northwestern Polytechnical University.
- 38. Ji Z., Guan Z., Li Z. (2016): Damage resistance property of stiffened composite panels under low-velocity impact. Journal of Beijing University of Aeronautics and Astronautics, 42(04): 751-761.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-2a324aa0-79f8-49a4-b512-4f37072b63c2