Analysis of laminated composite plates with fluid–structure interaction using multiscale modeling technique
Tóm tắt
A series of numerical modeling and simulations were conducted to understand the dynamic response and failure of a laminated composite plate which was supported by water and subjected to dynamic loading. The structure was modelled using the plate/shell finite elements with displacements degrees of freedom only. The water medium was stationary and modelled as an acoustic domain using the cellular automata technique. The two analysis techniques were coupled for fluid–structure interaction (FSI). Composite materials were modelled using the multiscale approach. The constituent material-based failure criteria (i.e. in terms of fiber, matrix, and fiber/matrix interface failures) were used to predict failure of the fibrous composite. Failure of the same composite plate was investigated and compared when the plate was supported by water or not to understand the effect of the FSI between the composite plates and water on the dynamic response and failure. The numerical study showed that the dynamic response and failure of the composite plate were very dependent on FSI, and the numerical study qualitatively confirmed previous experimental studies.
Tài liệu tham khảo
Abrate S (1994) Impact on laminated composites; recent advances. Appl Mech Rev 47(11):517–544
Alaei D, Kwon YW, Ramezani A (2019) Fluid-structure interaction on concentric composite cylinders containing fluids in the annulus. Multiscale Multidiscipl Model Exp Design 2(3):185–197
Aslan Z, Karakuzu R, Okutan B (2003) The response of laminated composite plates under low-velocity impact loading. Compos Struct 59:119–127
Chen W, Haroun MA, Liu F (1996) Large amplitude liquid sloshing in seismically excited tanks. Earthq Eng Struct Dyn 25(7):653–669
Craugh LE, Kwon YW (2013) Coupled finite element and cellular automata methods for analysis of composite structures with fluid-structure interaction. Compos Struct 102:124–137
Di Martino ES, Guadagni G, Fumero A, Ballerini G, Spirito R, Biglioli P, Redaelli A (2001) Fluid-structure interaction within realistic three-dimensional models of the aneurysmatic aorta as a guidance to assess the risk of rupture of the aneurysm. Med Eng Phys 23:647–655
Hosur MV, Jain K, Chowdhury F, Jeelani S, Bhat MR, Murthy CRL (2007) Low velocity impact response of carbon/epoxy laminates subjected to cold-dry and cold-moist conditioning. Compos Struct 79:300–311
Karamanos SA, Patkas LA, Platyrrachos MA (2006) Sloshing effects on the seismic design of horizontal-cylindrical and spherical industrial vessels. ASME J Pressure Vessel Technol 128(3):328–340
Kwon YW (2013) Analysis of laminated and sandwich composite structures using solid-like shell elements. Appl Compos Mater 20(4):355–373
Kwon YW (2014) Dynamic responses of composite structures in contact with water while subjected to harmonic loads. Appl Compos Mater 21(1):227–245
Kwon YW (2016) Multiphysics and multiscale modeling: techniques and application. CRC Press, Boca Raton
Kwon YW (2017) Finite difference based cellular automaton technique for structural and fluid-structure interaction applications. ASME J Pressure Vessel Technol 139:041301
Kwon YW (2020) Fluid-structure interaction of composite structures. Springer-Nature, Berlin
Kwon YW, Bang H-C (2000) Finite element method using MATLAB, 2nd edn. CRC Press, Boca Raton
Kwon YW, Bowling JD (2018) Dynamic responses of composite structures coupled through fluid medium. Multiscale Multidiscipl Model Exp Design 1(1):69–82
Kwon YW, Conner RP (2012) Low velocity impact on polymer composite plate in contact with water. Int J Multiphys 6(3):179–197
Kwon YW, Darcy J (2018a) Failure criteria for fibrous composites based on multiscale modeling. Multiscale Multidiscipl Model Exp Design 1(1):3–17
Kwon YW, Darcy J (2018b) Further discussion on newly developed failure criteria for fibrous composites. Multiscale Multidiscipl Model Exp Design 1(4):307–316
Kwon YW, Fox PK (1993) Underwater shock response of a cylinder subjected to a side on explosion. Comput Struct 48(4):637–646
Kwon YW, Kim C (1998) Micromechanical model for thermal analysis of particulate and fibrous composites. J Therm Stresses 21:21–39
Kwon YW, Panick CJ (2020) “Strain rate dependent failure criteria for fibrous composites using multiscale approach. Multiscale Multidiscipl Model Exp Design 3:11–22
Kwon YW, Park MS (2013) Versatile micromechanics model for multiscale analysis of composite structures. Appl Compos Mater 20(4):673–692
Kwon YW, Plessas SD (2014) Numerical modal analysis of composite structures coupled with water. Compos Struct 116:325–335
Kwon KW, Violette MA (2012) Damage initiation and growth in laminated polymer composite plates with fluid-structure interaction under impact loading. Int J Multiphys 6(1):29–42
Kwon YW, Owens AC, Kwon AS, Didoszak JM (2010) Experimental study of impact on composite plates with fluid-structure interaction. Int J Multiphys 4(3):259–271
Kwon YW, Violette MA, McCrillis RD, Didoszak JM (2012) Transient dynamic response and failure of sandwich composite structures under impact loading with fluid structure interaction. Appl Compos Mater 19(6):921–940
Kwon YW, Priest EM, Gordis JH (2013) Investigation of vibrational characteristics of composite beams with fluid-structure interaction. Compos Struct 105:269–278
Kwon YW, Teo HF, Park C (2016) Cyclic loading on composite beams with fluid structure interaction. Exp Mech 56(4):645–652
Kwon YW, South T, Yun KJ (2017) Low velocity impact to composite box containing water and baffles, composite structures. ASME J Pressure Vessel Technol 139(3):031304
Simsek FG, Kwon YW (2015) Investigation of material modeling in fluid-structure interaction analysis of an idealized three-layered abdominal aorta: aneurysm initiation and fully developed aneurysm. J Biol Phys 41(2):173–201
Strait LH, Karasek ML, Amateau MF (1992) Effects of stacking sequence on the impact resistance of carbon fiber reinforced thermoplastic toughened epoxy laminates. J Compos Mater 26(12):1725–1740
Weaver DS, Ziada S, Au-Yang MK, Chen SS, Paı̈doussis MP, Pettigrew MJ (2000) Flow-induced vibrations in power and process plant components—progress and prospects. ASME J Pressure Vessel Technol 122:339–348