Experimental investigation of the influence of wool structures on the stab resistance of woven body armor panels

Reiners, Priscilla; Kyosev, Yordan; Schacher, Laurence; Adolphe, Dominique; Küster, Katalin

doi:10.1177/0040517515596934

Cited by 16 publications

(17 citation statements)

References 19 publications

(17 reference statements)

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“…A recent review discussed the use of nano additives for stab and spike protection. 150 Future armor will use the nano additives such as carbon nanospheres, carbon nanotubes, and the structures of nanofibers to improve stab and spike protection.…”

Section: Textile Solutionsmentioning

confidence: 99%

Body armor for stab and spike protection, Part 1: Scientific literature review

Nayak

Crouch

Kanesalingam

et al. 2017

Textile Research Journal

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Since the invention of small arms ammunition, the human torso has required protection from hand-gun bullets, and today’s civil and military personnel are regularly clad in soft body armor systems to cope with these threats. However, increasingly, the threat spectrum has widened to include a plethora of both edged and pointed weapons. Over the past two decades in particular, this has required development of either specific soft armors to defeat that particular threat, or the development of multi-threat vests that can resist both hand-gun bullets and knife and spike attacks. In this review, we provide more details about the various material combinations that are used to defeat a knife or spike, since these armor materials are a lot different from the conventional aramid fabrics, and numerous, widely-different solutions are being pursued. The penetration mechanisms associated with the various forms of attack—stabbing and slashing—are discussed, as well as the use of new fibers, shear thickening fluids, and nano-materials in developing these body armor systems.

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Section: Textile Solutionsmentioning

confidence: 99%

Body armor for stab and spike protection, Part 1: Scientific literature review

Nayak

Crouch

Kanesalingam

et al. 2017

Textile Research Journal

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“…The failure mechanism of knife stab probe depends on the force of friction and shear force between the knife and the LPET fibers and basalt yarns, which in turn leads to the breakage of LPET fibers and basalt yarns [22,23]. Unlike the spike stab, the knife stab causes the breakage of the fibers as well as bundles of fibers of the sandwich composites [13,24]. The fractured patterns are shown in Figure 7(a) and (b).…”

Section: Resultsmentioning

confidence: 99%

“…Reiners et al. placing one-layer woven wool structure on the top and bottom of the panels increased the stab resistance of resulting body armor [13]. Suhaimi et al.…”

Section: Introductionmentioning

confidence: 99%

Polyethylene terephthalate/basalt stab-resistant sandwich composites based on the Box–Behnken design: Parameter optimization and empirical regression model

Zhang

et al. 2018

Jnl of Sandwich Structures & Materials

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In this study, the thicknesswise fibers of the low-melting polyethylene terephthalate (LPET) nonwoven fabrics are needle punched and intertwined with the intra-laminar basalt fibers (BF) of basalt plain woven fabric in order to strengthen the stab-resistant property of LPET/BF sandwich composites as well as to fabricate armor that is composed of less lamination layers. Two LPET nonwoven fabrics and a BF plain woven fabric as an interlayer are laminated and combined using a needle-punch reinforcing method. The response surface analysis based on the Box–Behnken design is used to examine the influences of structure parameters of low-melting PET nonwoven fabrics including areal density (AD) and manufacture parameters including needle punching density (ND), and depth of needle punch (DP) on the spike stab resistance, knife stab resistance, bursting resistance, and tensile property. An empirical regression model of AD, ND, and DP is thereby established. The test results show that the bursting strength and quasi-static stab resistance of sandwich composites are highly dependent on AD and ND. Likewise, DP has a significant influence on the knife stab resistance and bursting strength, while the tensile strength is solely dependent on ND. According to the empirical regress model, the acquired optimal needle punching parameters of sandwich composites are an AD of 400 g/m2, ND of 143.77 needles/cm2, and DP of 6.41 mm. The 95% confidence interval yielded by the empirical regression model is in conformity with the test results. The empirical regression model of the stab resistance is proven to provide effective prediction of the number of lamination layers required by armor in the future.

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“…Comparatively, knife-resistance force and energy of thermal treatment for 5 min are larger than other thermal durations, which represents the best knife-resistance performance. Under the action of knife, surficial nonwoven and interlayer BF are both damaged, and the failure surface presents a thin and long cut, which results from the cutting, friction between yarns, and friction between knife and yarns, as well as tensile plastic deformation [20]. The higher friction coefficient between yarns can generate a larger knife-resistance load and energy [21].…”

Section: Effects Of Thermal-bonded Time and Temperature On Knife Stabmentioning

confidence: 99%

Thermally Bonded PET–Basalt Sandwich Composites for Heat Pipeline Protection: Preparation, Stab Resisting, and Thermal-Insulating Properties

Zhang

Peng

et al. 2018

Applied Sciences

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Abstract:In order to solve the cost and bulky problems of buried thermal pipeline insulating materials, this study adopts basalt fabric and low-melting PET nonwoven to construct low-cost and light-weight pipeline thermal-insulating composites after needle punching and thermal bonding processes. Research result shows that thermal-bonded temperature affected the stab resistance and burst energy more significantly. As thermal-bonded temperature increased, knife resistance and spike resistance presented the upward and then downward trends, but the burst energy gradually decreased. Yarn pull-out result shows that the enhancement of stab resistance of intra-/inter-thermal-bonded structure resulted from the increment in the coefficient of friction between yarns. When PET-basalt sandwich composites were thermal-bonded at 140 • C for 5 min, the maximum knife and spike resistance were 147.00 N (1.99 J) and 196.30 N (1.11 J), respectively, and burst energy was 4.79 J, thermal conductivity reduced to 0.0073 W/(m·K). The resultant thermally bonded sandwich composites can be used as thermal-insulating protection for buried thermal pipeline.

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Experimental investigation of the influence of wool structures on the stab resistance of woven body armor panels

Cited by 16 publications

References 19 publications

Body armor for stab and spike protection, Part 1: Scientific literature review

Body armor for stab and spike protection, Part 1: Scientific literature review

Polyethylene terephthalate/basalt stab-resistant sandwich composites based on the Box–Behnken design: Parameter optimization and empirical regression model

Thermally Bonded PET–Basalt Sandwich Composites for Heat Pipeline Protection: Preparation, Stab Resisting, and Thermal-Insulating Properties

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