https://orcid.org/0000-0002-2111-8978
References
- Krzyżak A, Mazur M, Gajewski M, et al. Sandwich structured composites for aeronautics: methods of manufacturing affecting some mechanical properties. Int J Aero Eng. 2016;1–10.
- Li M, Wang S, Zhang Z, et al. Effect of structure on the mechanical behaviors of three-dimensional spacer fabric composites. Appl Compos Mater. 2009;16(1):1–4.
- Mori LF, Queheillalt DT, Wadley HN, et al. Deformation and failure modes of I-core sandwich structures subjected to underwater impulsive loads. Exp Mech. 2009;49(2):257–275.
- Mahfuz H, Islam S, Saha M, et al. Buckling of sandwich composites; effects of core–skin debonding and core density. Appl Compos Mater. 2005;12(2):73–91.
- Wang J, Waas AM, Wang H. Experimental study on the low-velocity impact behavior of foam-core sandwich panels. In: 53rd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference 20th AIAA/ASME/AHS Adaptive Structures Conference 14th AIAA. Honolulu, Hawaii. 2012. p. 1701.
- Gdoutos E, Daniel IM. Failure modes of composite sandwich beams. Theore Appl Mech. 2008;35(1–3):105–118.
- Manalo AC, Aravinthan T, Karunasena W, et al. Flexural behavior of structural fibre composite sandwich beams in flatwise and edgewise positions. Compos Struct. 2010;92(4):984–995.
- Sun S, Chen H. The interfacial fracture behavior of foam core composite sandwich structures by a viscoelastic cohesive model. Sci China Phys Mech & Astro. 2011;54(8):1481–1487.
- Khan MA, Syed AK, Ijaz H, et al. Experimental and numerical analysis of flexural and impact behaviour of glass/pp sandwich panel for automotive structural applications. Adv Compos Mater. 2018;27(4):367–386.
- Santhanakrishnan R, Samlal S, Joseph Stanley A, et al. Impact study on sandwich panels with and without stitching. Adv Compos Mater. 2018;27(2):163–182.
- Bao L, Miura Y, Kemmochi K. Improving bending characteristics of FRP sandwich structures with reinforcement webs. Adv Compos Mater. 2018;27(2):221–233.
- Ishikawa M, Irokawa C, Kogo Y, et al. Time-dependent deformation of ROHACELL-core CFRP sandwich panels. Adv Compos Mater. 2016;25(3):271–286.
- Neje G, Behera BK. Investigation of mechanical performance of 3D woven spacer sandwich composites with different cell geometries. Compos Part B Eng. 2019;160:306–314.
- Li DS, Zhao CQ, Jiang L, et al. Experimental study on the bending properties and failure mechanism of 3D integrated woven spacer composites at room and cryogenic temperature. Compos Struct. 2014;111:56–65.
- Zhao CQ, Li DS, Ge TQ, et al. Experimental study on the compression properties and failure mechanism of 3D integrated woven spacer composites. Mater Des. 2014;56:50–59.
- Fan H, Zhou Q, Yang W, et al. An experiment study on the failure mechanisms of woven textile sandwich panels under quasi-static loading. Compos Part B Eng. 2010;41(8):686–692.
- Van Vuure AW, Ivens JA, Verpoest I. Mechanical properties of composite panels based on woven sandwich-fabric preforms. Compos Part A: Appl Sci Manuf. 2000;31(7):671–680.
- Sadighi M, Hosseini SA. Finite element simulation and experimental study on mechanical behavior of 3D woven glass fiber composite sandwich panels. Compos Part B: Eng. 2013;55:158–166.
- Wang SK, Li M, Gu YZ, et al. Mechanical reinforcement of three-dimensional spacer fabric composites. Mater Sci Forum. 2010;654:2604–2607.
- Torun AR, Hoffmann G, Ünal A, et al. Spacer fabrics from hybrid yarn with fabric structures as spacer. In: Proceedings of 16thICCM. Kyoto, Japan; 2007. p. 1–5.
- Wang M, Cao H, Qian K. Mechanical Properties of Three-Dimensional Fabric Sandwich Composites. J EngFabr & Fiber. 2014;9(3):1–7.
- Mountasir A, Hoffmann G, Cherif C, et al. Development of non-crimp multi-layered 3D spacer fabric structures using hybrid yarns for thermoplastic composites. Procedia Mater Sci. 2013;2:10–17.
- Zhang JM, Reynolds CT, Peijs T. All-poly (ethylene terephthalate) composites by film stacking of oriented tapes. Compos Part A: Appl Sci Manuf. 2009;40(11):1747–1755.
- Anand AV, Venkatesh G, Anand P. Noval method for fabrication of 3-D spacer fabric composite and investigation of mechanical property. Inter J Mod Eng Res. 2014;4(9): 27-31.
- Lee HS, Hong SH, Lee JR, et al. Mechanical behavior and failure process during compressive and shear deformation of honeycomb composite at elevated temperatures. J Mater Sci. 2002;37(6):1265–1272.
- Fan H, Zhao L, Chen H, et al. Ductile deformation mechanisms and designing instructions for integrated woven textile sandwich composites. Compos Sci Technol. 2012;72(12):1338–1343.
- Li DS, Zhao CQ, Jiang N, et al. Fabrication, properties and failure of 3D integrated woven spacer composites with thickened face sheets. Mater Lett. 2015;148:103–105.
- Geerinck R, De Baere I, De Clercq G, et al. Development and characterization of composites consisting of woven fabrics with integrated prismatic shaped cavities. In: 7th world conference on 3D fabrics and their applications. Roubiax France; 2016. p. 1–10.
- Wang S, Li M, Zhang Z, et al. Properties of facesheet-reinforced 3-D spacer fabric composites and the integral multi-facesheet structures. J Reinf Plast Compos. 2010;6:793–806.