Stratospheric airships are controllable lighter-than-air aircraft and have great potential application in surveillance and communication. The envelopes, one of the main structures of a stratospheric airship, are generally made of flexible fabric composites to be lightweight, high strength, capable of containing lifting gas, and resistant to the harsh stratospheric environment. The composites, however, are prone to tearing. Hence, their tearing behavior has attracted great attention. This paper explores the meso-scale tearing mechanism of an envelope and the temperature influence on its tear strength via experiment and numerical simulation. Biaxial tear tests were conducted on cruciform specimens, which were contacted with liquids (cold alcohol or hot water) at different temperatures including -25, 20, 50, 80 °C. The specimens’ tear stresses were measured and the meso-scale tearing behavior was captured with a microscope. Besides, a novel finite element analysis model based on truss and spring elements was established to simulate the tearing behavior. It was found that the simulation result has a relative agreement with the tests. The simulation results show that the maximum tear stress of the envelope drops by 39.62% as the temperature rises from -60 °C to 80 °C and the tensile properties of yarns and matrix account for stress concentration around a crack tip. This work deeply reveals the meso-scale tearing mechanism of the envelope and provides a valuable reference for exploring tearing properties of flexible fabric composites.
[1] KANG W, SUH Y, WOO K, et al. Mechanical property characterization of film-fabric laminate for stratospheric airship envelope [J]. Composite Structures, 2006, 75(1/2/3/4): 151-155.
[2] ADAK B, JOSHI M. Coated or laminated textiles for aerostat and stratospheric airship [M]//Advanced textile engineering material. Hoboken, USA: John Wiley & Sons, Inc., 2018: 257-287.
[3] ZHAI H, EULER A. Material challenges for lighter-than-air systems in high altitude applications [C]//AIAA 5th ATIO and 16th Lighter-Than-Air Sys Tech. and Balloon Systems Conferences. Arlington, USA: AIAA, 2005: 7488.
[4] CHEN J, CHEN W, ZHOU H, et al. Central tearing characteristics of laminated fabrics: Effffect of slit parameter, off-axis angle, and loading speed [J]. Journal of Reinforced Plastics and Composites, 2017, 36(13): 921-941.
[5] CHEN Y, LI S, DING K, et al. Investigation of tear strength of an airship envelope fabric by theoretical method and uniaxial tear test [J]. Journal of Engineered Fibers and Fabrics, 2019, 14: 155892501987929.
[6] LIU L, LV M, XIAO H. Tear strength characteristics of laminated envelope composites based on single edge notched film experiment [J]. Engineering Fracture Mechanics, 2014, 127: 21-30.
[7] WANG F, XU W, CHEN Y, et al. Tearing analysis of a new airship envelope material under uniaxial tensile load [J]. IOP Conference Series: Materials Science and Engineering, 2016, 137: 012024.
[8] WANG F, CHEN Y, LIU G, et al. Investigation of the tearing properties of a new airship envelope fabric based on experimental and theoretical methods [J]. Journal of Industrial Textiles, 2019, 48(8): 1327-1347.
[9] MAEKAWA S, SHIBASAKI K, KUROSE T, et al. Tear propagation of a high-performance airship envelope material [J]. Journal of Aircraft, 2008, 45(5): 1546-1553.
[10] CHEN J, CHEN W. Central crack tearing testing of laminated fabric Uretek3216LV under uniaxial and biaxial static tensile loads [J]. Journal of Materials in Civil Engineering, 2016, 28(7): 04016028.
[11] TOPPING A D. The critical slit length of pressurized coated fabric cylinders [J]. Journal of Coated Fabrics, 1973, 3(2): 96-110.
[12] THIELE J. Approximation of envelope critical envelope critical slit length [C]//11th AIAA Lighter Than-Air Systems Technology Conference. Clearwater Beach, USA: AIAA, 1995: 15-18.
[13] MILLER T, MANDEL M. Airship envelopes: Requirements, materials and test methods [C]//AIAA 3rd International Airship Convention and Exhibition, Friedrichshafen, Germany: AIAA, 2000: 1-5.
[14] GUO G. Finite element analysis of pre-stretch effects on ballistic impact performance of woven fabrics [J]. Composite Structures, 2018, 200: 173-186.
[15] DAS S, JAGAN S, SHAW A, et al. Determination of inter-yarn friction and its effect on ballistic response of para-aramid woven fabric under low velocity impact [J]. Composite Structures, 2015, 120: 129-140.
[16] WEI Q, YANG D, GU B, et al. Numerical and experimental investigation on 3D angle interlock woven fabric under ballistic impact [J]. Composite Structures, 2021, 266: 113778.
[17] GAO Z, CHEN L. A review of multi-scale numerical modeling of three-dimensional woven fabric [J]. Composite Structures, 2021, 263: 113685.
[18] DYKE P, HEDGEPETH J. Stress concentrations from single-filament failures in composite materials [J]. Textile Research Journal, 1969, 39(7): 618-626.
[19] BEYERLEIN I, PHOENIX S. Stress concentrations around multiple fiber breaks in an elastic matrix with local yielding or debonding using quadratic influence superposition [J]. Journal of the Mechanics and Physics of Solids, 1996, 44(12): 1997-2039.
[20] GODFREY T, ROSSETTOS J, BOSSELMAN S. The onset of tearing at slits in stressed coated plain weave fabrics [J]. Journal of Applied Mechanics, 2004, 71(6): 879-886.
[21] WANG F, CHEN Y, LIU G, et al. Experimental investigation and theoretical analysis of tear propagation of GQ-6 airship envelope [J]. Journal of Industrial Textiles, 2018, 48(1): 304-321.
[22] BIGAUD D, SZOSTKIEWICZ C, HAMELIN P. Tearing analysis for textile reinforced soft composites under mono-axial and bi-axial tensile stresses [J]. Composite Structures, 2003, 62(2): 129-137.
[23] DU Y, JIANG J, CHEN N. Research on heat resistance of Vectran fiber [J]. Fiber Reinforced Plastics/Composites, 2014(4): 23-26 (in Chinese).
[24] HOSHIRO H, ENDO R, SLOAN F. Vectran?: Super fiber from the thermotropic crystals of rigid-rod polymer [M]//High-performance and specialty fibers. Tokyo: Springer, 2016: 171-190.
[25] LV J, ZHANG Y, GAO H, et al. Influence of processing and external storage conditions on the performance of envelope materials for stratospheric airships [J]. Advances in Space Research, 2021, 67(1): 571-582.
[26] XIE W, WANG X, DUAN D, et al. Mechanical properties of UN-5100 envelope material for stratospheric airship [J]. The Aeronautical Journal, 2021, 125(1285): 472-488.
[27] Membrane Structures Association of Japan. Test method for elastic constants of membrane materials [S]. Tokyo: Membrane Structures Association of Japan, 1995.
[28] Airship design criteria: FAA-P-8110-2 [S]. Washington: US Department of Transportation, 1995.
[29] SHI T, CHEN W, GAO C, et al. Biaxial constitutive relationship and strength criterion of composite fabric for airship structures [J]. Composite Structures, 2019, 214: 379-389.
[30] BLABER J, ADAIR B, ANTONIOU A. Ncorr: opensource 2D digital image correlation Matlab software [J]. Experimental Mechanics, 2015, 55(6): 1105-1122.
[31] Kuraray. VectranTM enhance transform discover liquid crystal polymer fiber technology [EB/OL]. [2021-10- 27]. https://www.vectranfifiber.com/wp-content/uploads/2015/12/Kuraray-Vectran-Brochure.pdf.
[32] LIU B, BAI G, XU Z, et al. Experimental study and finite element modeling of bond behavior between recycled aggregate concrete and the shaped steel [J]. Engineering Structures, 2019, 201: 109840.
[33] KAWABATA S, NIWA M, KAWAI H. The finite deformation theory of plain-weave fabrics Part I: The biaxial-deformation theory [J]. The Journal of the Textile Institute, 1973, 64(1): 21-46.
[34] HE R, SUN X, WU Y. Central crack tearing test and fracture parameter determination of PTFE coated fabric [J]. Construction and Building Materials, 2019, 208: 472-481.
[35] SUN X, HE R, WU Y. A novel tearing residual strength model for architectural coated fabrics with central crack [J]. Construction and Building Materials, 2020, 263: 120133.
