Hybrid composite materials (HCMs) containing knitted fabric as reinforcement often improve the mechanical properties and retard failure process in the loaded structure. In the present investigation, using numerical methods, was modeled damage accumulation process in a HCM, prepared by uniformly impregnating a knitted fabric of basalt microfiber yarn with epoxy resin having dispersed fine oil shale ash (OSA) particles. The HCM plate was investigated experimentally and performing numerical modelling of damage accumulation in it. The elastic modulus of the polymer matrices at different OSA concentrations was experimentally measured. This data was then used in a finite element model to calculate stresses in the reinforced textile inside the loaded plate. Impregnated yarns in the textile were modeled as macrofibers (MFs) with averaged properties, and their geometry was described using the Leaf–Glaskin approach. Next, the damage accumulation process was simulated under an external unidirectional tensile load. Depending on the applied load, different parts of the MF loops experience overloading. At some point, one of the most overloaded MF cross-sections breaks, as described using the probabilistic Weibull function. The Weibull distribution parameters were accepted using data for single fiber rupture. This leads to increased overload on the cross-sections of adjacent MF loops and eventually their breakage as well. A stochastic numerical model of sequential MF rupture accumulation was developed to describe the probabilities of defects that consist of various numbers of adjacent broken MFs. Analytical and stochastic methods were used to determine the load-carrying capacity and the accumulation of defects of different sizes in the HCM plate.
AbotJLYasminAJacobsenAJ, et al. (2004) In-plane mechanical, thermal, and viscoelastic properties of a satin fabric carbon/epoxy composite. Composites Science and Technology64: 263–268.
2.
AndersonsJJoffeRHojoM, et al. (2002) Glass fibre strength distribution determined by common experimental methods. Composites Science and Technology62: 131–145.
3.
AndrewJJSrinivasanSMArockiarajanA, et al. (2019) Parameters influencing the impact response of fiber-reinforced polymer matrix composite materials: a critical review. Composite Structures224: 111007.
4.
AtmakuriAPaleviciusAVilkauskasA, et al. (2020) Review of hybrid fiber based composites with nano particles—Material properties and applications. Polymers12: 2088. (Open access).
5.
AvestonJSillwoodJM (1976) Synergistic fiber strengthening in hybrid composites. Journal of Materials Science11: 1877–1883.
6.
BogenfeldRKreikemeierJWilleT (2018) Review and benchmark study on the analysis of low velocity impact on composite laminates. Engineering Failure Analysis86: 72–99.
7.
DürethCWeckDBöhmR, et al. (2020) Determining the damage and failure behavior of textile reinforced composites under combined in-plane and out-of-plane loading. Materials13: 4772.
8.
Engelbrecht-WiggansAEPhoenixSL (2016) Comparison of maximum likelihood approaches for analysis of comp site stress rupture data. Journal of Materials Science51: 6639–6661.
9.
FeihSManatponKMathysZ, et al. (2009) Strength degradation of glass fibers at high temperatures. Journal of Materials Science44(2): 392–400.
10.
GutansJTamuzhV (1984) Scale effect of the Weibull distribution of fibre strength. Mechanics of Composite Materials6: 1107–1109.
11.
HamadaHFujitaAYokoyamaA, et al. (1994) United approach for predicting mechanical behaviors of textile composites. In: ACS-Meeting Proceedings. Delaware, USA, pp. 377–385.
12.
HamadaHSugimotoKNakaiA, et al. (2000) Mechanical properties of knitted fabric composites. Journal of Reinforced Plastics and Composites19(05): 364–376.
13.
HansenA (2020) The three extreme value distributions: an introductory review. Frontiers in Physics8. 10 December 2020, Sec. Interdisciplinary Physics. DOI: 10.3389/fphy.2020.604053.
14.
HardakerMRichardsonMOW (1980) Trends in hybrid composite technology. Polymer-Plastics Technology and Engineering15(2): 169–182.
15.
HuJ (2008) Introduction to three-dimensional fibrous assemblies. In: HuJ (ed) 3-D Fibrous Assemblies Properties, Applications and Modelling of Three-Dimensional Textile Structures. Cambridge: Woodhead Publishing, pp. 1–32.
16.
HuangZMZhangYRamakrishnaS (2001) Modeling of the progressive failure behavior of multilayer knitted fabric-reinforced composite laminates. Composites Science and Technology61(14): 2033–2046.
17.
HuysmansGVerpoestIVan HoutteP (2001) A damage model for knitted fabric composites. Composites Part A: Applied Science and Manufacturing32: 1465–1475.
18.
JacobsenAJLuoJJDanielIM (2004) Characterization of constitutive behavior of satin weave fabric composite. Journal of Composite Materials38(7): 555–565.
19.
JafarliIMačanovskisAGjerløwE, et al. (2024) Mechanical properties study of epoxy and concrete based composite material reinforced with oil shale ash. In: 23rd international scientific conference engineering for rural development, ERD, Jelgava, 22–24 May 2024. doi: 10.22616/ERDev.2024.23.TF029 (Open Access).
20.
JerzynskaAEgnerH (2023) Energy equivalence based estimation of hybrid composites mechanical properties. Materials16: 4215. (Open access).
21.
JuJWKoYFRuanHN (2008) Effective elastoplastic damage mechanics for fiber reinforced composites with evolutionary partial fiber debonding. International Journal of Damage Mechanics17(6): 493–537.
22.
Kalpokaitė-DičkuvienėRPitakIBaltušnikasA, et al. (2023) Functional and microstructural alterations in hydrated and freeze–thawed cement-oil shale ash composites. Case Studies in Construction Materials19: e02302. (Open Access).
23.
KaterelosDTGKrasnikovsAVarnaJ (2015) Variational models for shear modulus of symmetric and balanced laminates with cracks in 90-layer international. International Journal of Solids and Structures71: 169–179. (Open Access).
24.
KawAK (2006) Mechanics of Composite Materials. Mechanical engineering series. Boca Raton, FL: Taylor & Francis, p. 457,ISBN 0-8493-1343-0.
25.
KononovaOKrasnikovsADzelzitisK, et al. (2011) Mechanical properties modeling and experimental verification for cotton knitted fabric composites. Estonian Journal of Engineering17(1): 39–50.
26.
KononovaOKrasnikovsAKharkovaG, et al. (2012) Mechanical properties characterization by inverse technique for composite reinforced by knitted fabric. Part 1. Material modeling and direct experimental mechanical properties evaluation. Journal of Vibroengineering14(2): 681–690.
27.
KorabelnikovYGTamuzhVPSiluyanovOF, et al. (1984) Scale effect of the strength of fibers and properties of unidirectional composites based on them. Mechanics of Composite Materials20: 129–134.
28.
KrasnikovsAKononovaOMachanovskisA, et al. (2012) Mechanical properties characterization for composite reinforced by knitted fabric using inverse technique: Part 2. Mechanical properties experimental evaluation by frequency eigenvalues method. Journal of Vibroengineering14(2): 691–698.
29.
LeeMMata-FalcónJKaufmannW (2021) Load-deformation behaviour of weft-knitted textile reinforced concrete in uniaxial tension. Materials and Structures54: 210.
30.
LeongKHRamakrishnaSHuangZM, et al. (2000) The potential of knitting for engineering composites—A review. Composites Part A: Applied Science and Manufacturing31: 197–220.
31.
MaheshSPhoenixSLBeyerelinIJ (2002) Strength distributions and size effects for 2D and 3D composites with Weibull fibers in an elastic matrix. International Journal of Fracture115: 41–85.
32.
MobasherB (2011) Mechanics of Fiber and Textile Reinforced Cement Composites. Boca Raton, FL: CRC Press, p. 473,ISBN-10: 1439806608.
33.
MorganP (2005) Carbon Fibers and Their Composites, 1st ed.CRC Press. DOI: 10.1201/9781420028744.
Pakkam GabrielVRLoukilMSVarnaJ (2021) Analysis of intra-laminar cracking in 90-plies of GF/EP laminates with distributed ply strength. Journal of Composite Materials55(26): 3925–3942.
36.
PanditaSDFalconetDVerpoestI (2002) Impact properties of weft knitted fabric reinforced composites. Composites Science and Technology62(7-8): 1113–1123.
37.
PhoenixSLSchwartzPRobinsonHHIV (1988) Statistics for the strength and lifetime in creep-rupture of model carbon/epoxy composites. Composites Science and Technology32: 81–120.
RalphCLemoinePSummerscalesJ, et al. (2019) Relationships among the chemical, mechanical and geometrical properties of basalt fibers. Textile Research Journal89(15): 3056–3066.
40.
RamakrishnaS (1997) Characterization and modeling of the tensile properties of plain weft-knit fabric-reinforced composites. Composites Science and Technology57: 1–22.
41.
RamakrishnaSCuongNKHamadaH (1997a) Tensile properties of plain weft knitted glass fiber fabric reinforced epoxy composites. Journal of Reinforced Plastics and Composites16(10): 946–966.
42.
RamakrishnaSHamadaHChengKB (1997b) Analytical procedure for the prediction of elastic properties of plain knitted fabric-reinforced composites. Composites Part A: Applied Science and Manufacturing28: 25–37.
43.
RamakrishnaSHullD (1994) Tensile behavior of knitted carbon-fiber fabric/epoxy laminates - part II: prediction of tensile properties. Composites Science and Technology50: 249–258.
44.
RiosCROginSLLekakouC, et al. (1999) The relationship between fibre architecture and cracking damage in a knitted fabric reinforced composite. Proceedings/ICCM12proceedings/site/papers/pap1035.pdf. http://www.iccmcentral.
45.
RiosCROginSLLekakouC, et al. (2007) A study of damage development in a weft knitted fabric reinforced composite. Part 1: experiments using model sandwich laminates. Composites Part A: Applied Science and Manufacturing38(7): 1773–1793.
46.
SimJKangYKimBJ, et al. (2020) Preparation of fly ash/epoxy composites and its effects on mechanical properties. Polymers12(1): 79. (Open access).
47.
SutherlandLSGuedes SoaresC (1997) Review of probabilistic models of the strength of composite materials. Reliability Engineering and System Safety56: 183–196.
48.
VarnaJBerglundLAKrasnikovsA, et al. (1997) Crack opening geometry in cracked composite laminates. International Journal of Damage Mechanics6(1): 96–118.
49.
VavaliyaUJafarliIKononovaO, et al. (2024) Mechanical properties investigation of UD hybrid Basalt fiber/epoxy composite depending on its length. In: 23rd international scientific conference engineering for rural development, ERD, Jelgava, 22–24 May 2024. DOI: 10.22616/ERDev.2024.23.TF124 (Open Access).
50.
WolfCHDürethCWünscheM, et al. (2025) Fatigue delamination growth in textile-reinforced plastics under combined interlaminar shear and compression: numerical and experimental characterization. Composite Structures371: 119384.
51.
WuXFZholobkoO (2020) Experimental study of the probabilistic fatigue residual strength of a carbon fiber-reinforced polymer matrix composite. Journal of Composites Science4: 173.
52.
YanLWangXWuH, et al. (2022) Damage and failure mechanisms of biaxial weft-knitted reinforced composites via meso-scale finite element modeling. Journal of Industrial Textiles51(1S): 1592S–1611S.
53.
ZnoagaMTanasaF (2014) Complex textile structures as reinforcement for advanced composite materials. In: International conference of scientific paper AFASES.
54.
ZwebenCRosenB (1970) A statistical theory of material strength with application to composite materials. Journal of the Mechanics and Physics of Solids18: 189–206. DOI: 10.1016/0022-5096(70)90023-2.
