Fabric Layers Research Articles

Sustainable innovation in ballistic vest design: Exploration of polyurethane-coated hemp fabrics and reinforced sandwich epoxy composites against 9 mm and .40 S&W bullets

This research aimed to evaluate the bulletproof capabilities of hemp fabrics and optimize the design factors for effective ballistic vests. Three main aspects were investigated: enhancing toughness with polyurethane-coated hemp fabrics, determining optimal placement of fabric-reinforced hemp epoxy composites in various configurations, and identifying the optimal number of fabric layers for performance against 9 mm and .40 S&W bullets. Penetration depth was measured in ballistic gelatin to analyze the results. The study showed strong statistical correlations between factor variables and penetration depth shifts. The most effective strategies included polyurethane-coated hemp on all layers and increased layering. The ammunition of 9 mm bullets exhibited the least penetration depth when tested against the sandwich-reinforced configuration. In contrast, the larger .40 S&W bullets demonstrated that the frontal arrangement yielded the minimum penetration depth. Notably, 9 mm bullets penetrated 1.25 times deeper than .40 S&W bullets. These findings emphasize hemp fabric's potential for reliable ballistic vests. Utilizing polyurethane-coated hemp fabric in epoxy composites within a sandwich reinforcement of at least 212 layers is recommended to stop 9 mm bullets effectively. The research contributes valuable insights to sustainable ballistic vest development, utilizing natural materials with exceptional bullet protection capabilities.

Characterization and ballistic performance of hybrid jute and aramid reinforcing graphite nanoplatelets in high-density polyethylene nanocomposites

Hybrid nanocomposites have emerged as a promising solution for engineering applications associated with reduced costs and weight aiming to enhance performance in special areas such as ballistic protection. This study delves into the development of hybrid nanocomposites featuring a high-density polyethylene matrix modified with graphite nanoplatelets and reinforced by aramid and jute fabrics. The incorporation of GNP significantly influences the crystalline structure of the GNP/HDPE matrix, as evidenced by Raman and X-ray diffraction analyses. Furthermore, it assumes an important role in modifying the crystallization and glass transition temperatures (Tc and Tg) and influencing the dynamic mechanical behavior. Specifically, it increases viscoelastic stiffness, raises the storage modulus by more than 30 %, and reduces the tanδ value. In addition, replacing 5 layers of jute fabric with an equivalent number of aramid layers maintains comparable ballistic performance to a 20-layer aramid nanocomposite. This substitution yields a remarkable 659.41 J of absorbed energy and a limit velocity of 405.72 m/s. Additionally, a hybrid nanocomposite comprising 10 layers each of jute and aramid showcases impressive ballistic resistance against 9 mm caliber ammunition, achieving 419.84 J of absorbed energy and a limit velocity of 320.13 m/s. Scanning electron microscopy analysis exposes the intricate fracture mechanisms, encompassing phenomena such as crazing, GNP/HDPE fibrillation, fiber rupture, and debonding. These mechanisms are significant in the composite's energy absorption during a projectile impact. Moreover, a cost-benefit analysis underscores the potential of hybrid nanocomposites in ballistic protection by simultaneously reducing both helmet weight and cost in 7 % and 40 %, respectively.

Effect of reinforcement ratio and textile pre-impregnation on the mechanical properties of flax textile reinforced sulfoaluminate matrix

This study evaluates the effect of reinforcement ratio and textile pre-impregnation on the tensile behavior of flax textile, embedded in an inorganic CSA matrix (sulfoaluminate cementitious matrix), known as Fabric Reinforced Cementitious Matrix (FRCM). Two reinforcement ratios of (3 and 6%) and two impregnation techniques (polymeric and mineral) are applied. Direct tensile tests are conducted on FRCM specimens as well as on bare flax textiles featuring three configurations: NP (non-impregnated), PP (polymeric-impregnated), and PM (mineral-impregnated), between 1L (one layer) and 2L (two layers) of flax textile. The results show a direct correlation between the reinforcement ratio and the enhancement of mechanical properties, with a notable 44% increase in mechanical strength observed for NP FRCM specimens between 1L and 2L of flax textile. Mineral pre-impregnation enhances yarn-cement matrix bonding inside FRCM, while FRCM specimens with polymeric-impregnated textiles have limited influence on the mechanical properties due to premature failure. Polymeric impregnation has a pronounced effect when applied to bare flax textiles, with PP flax textiles demonstrating exceptional mechanical strength and rigidity, reaching up to 480 MPa and 37 GPa, respectively. In contrast, this effect was mitigated when employing PP textiles in FRCM specimens, where the lowest fabric efficiency reached 12% for the 2L.PP configuration suggests significant chemical incompatibility between epoxy resin and CSA matrix. Mineral-impregnated specimens display consistent efficiency regardless of reinforcement ratio, suggesting a novel and homogeneous distribution of cement matrix particles within the yarns of textiles. Two distinct failure modes of FRCM are observed in this study, a delamination for PP configurations and a fiber pullout for NP and PM configurations. No effect of reinforcement ratio is remarked on the failure mode. The cracking mode in PM FRCM configurations showcased improved aesthetics, durability, and elongation after rupture (6.28%). As a result, 2L.PM FRCM is the best configuration in terms of mechanical strength, rigidity, ductility, and durability.

Comparing the mechanical properties of single and double layer 100% cotton denim fabrics for motorcycle protective clothing

India has one of the highest rates of motorcycle accidents in the world. Protective clothing is required for motorcyclists in India since it can lessen the severity of injuries sustained in an accident. The purpose of this research is to examine the performance of single and double layers of denim fabrics developed. Focusing on the potential use in motorcycle protective clothing, 100% cotton single-layer (SL) fabrics with masses ranging from 370, 390, 410, 430, and 450 g/m2 are developed. The 100% cotton single-layer (SL) fabrics are taken as double layers (DL) for testing and analysis. Both single and double-layer fabrics were tested for physical properties and mechanical properties such as tensile, tear strength, and abrasion resistance. Overall performances of double-layer (DL) fabrics were superior compared to that of single-layer fabrics since double-layer fabrics contain two layers of fabrics to withstand stress and tear, and also provide better abrasion resistance.

Experimental investigation on flexural behavior of textile-reinforced concrete: effect of reinforcement type and dune sand addition

Purpose To contribute to the identification of the parameters influencing the behavior of textile-reinforced concrete (TRC), the purpose of this paper is to investigate the flexural behavior of TRC-based plates under four-point bending notably designed in the context of sustainable development and the substitution of mortar components with natural and abundant materials. Design/methodology/approach An extensive experimental campaign was focused about two main parameters. The first one emphases the textile reinforcements, such as the number of layers, the nature and the textile mesh size. In the second step, the composition of the mortar matrix was explored through the use of dune sand as a substitute of the river one. Findings Test results in terms of load-displacement response and failure patterns were highlighted, discussed and confronted to literature ones. As key findings, an increase of the load-bearing capacity and ductility, comparable to the use of an industrially produced second textile layer was recorded with the use of dune sand in the mortar mix design. The designed ecofriendly samples with economic concerns denote the significance of obtained outcomes in this research study. Originality/value The novelty of the present work was to valorize the use of natural dune sand to design new TRC samples to respond to the environmental and economical requirements. The obtained values provide an improved textiles–matrix interface performance compared to classical TRC samples issued from the literature.

The correlation between multilevel micro-nano structures and thermal conductivity of nanoporous phenolic composites reinforced by needled fiber preforms

Nanoporous phenolic composites (NPC) are the most promising ablative thermal protection materials, but accurately modeling and effective thermal conductivity (λeff) prediction remains a significant challenge due to their intricate micro-nano structures. Herein, a modified generation method, which incorporates structural parameters from micro-CT, is proposed to develop precise NPC structural models for assessing the correlation between micro-nano structures and λeff. The Lattice Boltzmann method and Fourier's law are employed to predict their λeff, with only 8% discrepancy from experiment. Results from phenolic matrix reveals that once the porosity of matrix exceeds 60%, any further increases have a limited effect on λeff due to the Knudsen effect at nanoscale. Additionally, fiber structure analysis indicates that an increase in yarn height or width results in a decrease in λeff, yet if product of the two is maintained, λeff remains unchanged as the yarn cross-sectional area remains constant. Furthermore, investigation into stacked preforms demonstrates that λeff increases linearly with the number of fabric layers at a constant felt density, but decreases at a constant preform density owing to densely packed yarns. These results reveal the correlation between multilevel micro-nano structures and thermal conductivity of NPC, providing important guidance for optimizing the NPC thermal insulation performance.

Textile-Based Body Capacitive Sensing for Knee Angle Monitoring.

Monitoring human movement is highly relevant in mobile health applications. Textile-based wearable solutions have the potential for continuous and unobtrusive monitoring. The precise estimation of joint angles is important in applications such as the prevention of osteoarthritis or in the assessment of the progress of physical rehabilitation. We propose a textile-based wearable device for knee angle estimation through capacitive sensors placed in different locations above the knee and in contact with the skin. We exploited this modality to enhance the baseline value of the capacitive sensors, hence facilitating readout. Moreover, the sensors are fabricated with only one layer of conductive fabric, which facilitates the design and realization of the wearable device. We observed the capability of our system to predict knee sagittal angle in comparison to gold-standard optical motion capture during knee flexion from a seated position and squats: the results showed an R2 coefficient between 0.77 and 0.99, root mean squared errors between 4.15 and 12.19 degrees, and mean absolute errors between 3.28 and 10.34 degrees. Squat movements generally yielded more accurate predictions than knee flexion from a seated position. The combination of the data from multiple sensors resulted in R2 coefficient values of 0.88 or higher. This preliminary work demonstrates the feasibility of the presented system. Future work should include more participants to further assess the accuracy and repeatability in the presence of larger interpersonal variability.

Pull‐off capacity of FRP–concrete composite bonded with epoxy/geopolymer at elevated temperature

AbstractExternally bonded strengthening technique to the concrete has been widely used with epoxy adhesive. However, the adhesive is considerably weak against high temperatures, which has been regarded as the critical point in the loss of integrity of the strengthened system. Alternatively, geopolymer materials have shown an excellent performance at high temperatures, thus, their potential to be used as adhesive material has been investigated in this work. In experimentation, the composite specimens were developed using both types of adhesives, epoxy and geopolymer, and their performance was evaluated at three temperature levels (20, 60, and 120°C) by conducting pull‐off strength tests and classifying their failure modes. It was observed that the strength of concrete and epoxy was reduced with temperature. In contrast, the strength of geopolymer‐based adhesives strength was increased due to the reactivity of the precursor at high temperatures. Also, bond strength was reduced for both composite specimens at elevated temperatures. The highest bond strength was observed for the epoxy‐based adhesive system at 20°C, and about 70% loss in bond strength was observed when exposed to 120°C. The failure mode was also shifted from concrete to adhesive interface failure, that is, failure between the adhesive and the fiber fabric layer. The geopolymer‐based adhesive system has lower strength than its counterpart at all temperature levels, and the failure mode was adhesive interface failure. To enhance the bonding capacity at high temperatures, efforts are being made by adding different minerals has been employed. From the experimental results, it was found that there were some improvements, however, it was still less than that of epoxy‐based system. Further optimization of the geopolymer adhesive using minerals is required and then high‐thermal resistance geopolymer adhesive can be established.

Tribological Properties of a Carbon Fabric Composite with Different Orientations of Fabric Layers to the Movement Direction during Friction

Tribological Properties of a Carbon Fabric Composite with Different Orientations of Fabric Layers to the Movement Direction during Friction

Triboelectric Nanogenerators Based on Nanostructured Layers of Zinc Oxide Deposited on Carbon Fabric

In this work, to obtain textile triboelectric layers for wearable flexible triboelectric nanogenerators (TENGs), we used two modes of growing nanostructured zinc oxide (ZnO) arrays on a carbon fabric (CF) using the automatic Successive Ionic Layer Adsorption and Reaction (SILAR) method. To produce a CF/ZnO_nr triboelectric textile with an array of intergrown short ZnO nanorods, we used a pre-coating of carbon fibers with ZnO seed layers. When the ZnO layer was fabricated by automatic SILAR on bare carbon fabric, we obtained the CF/ZnO_ns textile with an array of interconnected ZnO nanosheets 50–100 nm thick. As a proof of concept, we developed and tested two prototypes of flexible vertical contact–separation mode CF/ZnO_nr/PET/ITO and CF/ZnO_ns/PET/ITO TENGs, in which a gap was involuntarily formed between the smooth PET layer and the woven carbon textile coated with nanostructured ZnO films. In pressing tests with a force of ~5 N (pressure ~33 kPa), the CF/ZnO_ns/PET/ITO TENG created a higher open-circuit voltage up to 30 V and a higher maximum surface charge density of 1.3 μC/m2. In the successive press–release tests, this TENG showed an output voltage of 3.6 V, a current density of 1.47 μA/cm2, and a power density of 1.8 µW/cm2, confirming its effectiveness.

The Behavior of Glass Fiber Composites under Low Velocity Impacts.

This paper presents experimental results on the behavior of a class of glass fiber composites under low velocity impacts, in order to analyze their usage in designing low velocity impact-resistant components in car and marine industries. Also, a finite element model at the meso level (considering yarn as a compact, homogenous and isotropic material) was run with the help of Ansys Explicit Dynamics in order to point out the stages of the failure and the equivalent stress distribution on the main yarns in different layers of the composite. The composites were manufactured at laboratory scale via the laying-up and pressing method, using a quadriaxial glass fiber fabric (0°/+45°/90°/-45°) supplied by Castro Composites (Pontevedra, Spain) and an epoxy resin. The resin was a two-component resin (Biresin® CR82 and hardener CH80-2) supplied by Sika Group (Bludenz, Austria). The mass ratio for the fabric and panel was kept in the range of 0.70-0.77. The variables for this research were as follows: the number of layers of glass fiber fabric, the impact velocity (2-4 m/s, corresponding to an impact energy of 11-45 J, respectively) and the diameter of the hemispherical impactor (Φ10 mm and Φ20 mm) made of hardened steel. The tests were performed on an Instron CEAST 9340 test machine, and at least three tests with close results are presented. We investigated the influence of the test parameters on the maximum force (Fmax) measured during impact, the time to Fmax and the duration of impact, tf, all considered when the force is falling to zero again. Scanning electron microscopy and photography were used for discussing the failure processes at the fiber (micro) and panel (macro) level. At a velocity impact of 2 m/s (corresponding to an impact energy of 11 J), even the thinner panels (with two layers of quadriaxial glass fiber fabric, 1.64 mm thickness and a surface density of 3.51 kg/m2) had only partial penetration (damages on the panel face, without damage on panel back), but at a velocity impact of 4 m/s (corresponding to an impact energy of 45 J), only composite panels with six layers of quadriaxial fabric (5.25 mm thickness and a surface density of 9.89 kg/m2) presented back faces with only micro-exfoliated spots of the matrix for tests with both impactors. These results encourage the continuation of research on actual components for car and naval industries subjected to low velocity impacts.

Ghost-Stitching American Politics

Ghost-Stitching American Politics

On the Analyses of Cure Cycle Effects on Peel Strength Characteristics in Carbon High-Tg Epoxy/Plasma-Activated Carbon PEEK Composite Interfaces: A Preliminary Inquiry

In this study, a high-Tg aerospace-grade epoxy composite plate was co-curing welded using a unidirectional PEEK thermoplastic carbon fibre tape to develop advanced composite joints. To account for the surface roughness and the weldability of carbon–epoxy/carbon–PEEK composites, plasma treatments were performed. The co-curing was conducted by the following steps: each treated thermoplastic tape was first placed in the mould, and followed by nine layers of dry-woven carbon fabrics. The mould was sealed using a vacuum bag, and a bi-component thermoset (RTM6) impregnated the preform. To understand the role of curing kinetics, post-curing, curing temperature, and dwell time on the quality of joints, five cure cycles were programmed. The strengths of the welded joints were investigated via the interlayer peeling test. Furthermore, cross-sections of welded zones were assessed using scanning electron microscopy in terms of the morphology of the PEEK/epoxy interphase after co-curing. The preliminary results showed that the cure cycle is an important controlling parameter for crack propagation. A noticeable distinction was evident between the samples cured first at 140 °C for 2 h and then at 180 °C for 2 h, and those cured initially at 150 °C for 2 h followed by 180 °C for 2 h. In other words, the samples subjected to the latter curing conditions exhibited consistently reproducible results with minimal errors compared to different samples. The reduced errors confirmed the reproducibility of these samples, indicating that the adhesion between CF/PEEK and CF/RTM6 tends to be more stable in this curing scenario.

Experimental investigation and design-oriented model for concrete column confined with textile reinforced geopolymer composites

The present study deals with an experimental investigation on concrete columns (small-scale) confined with TRM (textile reinforced mortar) having geopolymer-based matrix. Two different types of fibers for the textile were used, namely basalt and glass, while the number of layers varied ranging between 2 and 4. Furthermore, hybrid textile confinement, obtained by installing glass textile inner layer coupled with basalt textile outer layer, was tested. In addition, a pilot sample was also considered with geopolymer matrix-only confinement. From the experimental results, the confinement was found to be effective in increasing axial strength proportionally to the number of textile layers. An increase in the compressive strength of 43.7% and 47.7% was recorded for the four layers of glass and basalt textile, while a maximum axial ductility of 2.18 and 2.19 was obtained for three and four layers of glass and basalt textiles, respectively. Furthermore, both the hybrid textile and the matrix-only configurations have demonstrated a significant improvement in strength. Based on the experimental findings, a theoretical model was empirically calibrated to predict the compressive strength of TRM-confined columns. While the existing models on TRM generally neglect the matrix’s contribution according to the FRP-based (fibre reinforced polymer) theory, the present study reports and discusses a new design-oriented model considering both the confining matrix and textile effects.

Near simultaneous multiple fragment impacts on aramid fabrics: Effects of velocity, dispersion and time intervals

Protection against fragment impacts is a critical concern across various applications. Conventional standardised methods use single-impact tests as a simplified approach for evaluating material resistance against impacting fragments. An alternative, near simultaneous triple impact test was implemented for testing protective equipment and materials against fragmentation, effectively simulating the impact of a dense cluster of fragments. Aramid fabrics, the most common protective measure against fragments, exhibit up to 13 % reduced ballistic resistance under triple impacts opposed to single impact tests signifying the importance of a multi-hit test method when evaluating protection against fragments.In this article, a finite element model is developed to conduct a detailed analysis of the dynamic interactions within a triple impact test. This analysis decouples and isolates the various contributing factors, including: the impacting velocity, the dispersion between impacts, the impact positions with respect to the main axes of material symmetry and the time intervals between the impacting projectiles. The model describes 15 layers of aramid fabric, in a detailed discrete mesoscale format, subjected to single, dual and triple impacting 1.102 g Fragment Simulating Projectiles (FSP) in different configurations using the finite element package LS-Dyna.As anticipated, penetrability increases when the distance between two impacting projectiles decreases. Additionally, on-axis impacts are more likely to result in perforation due to increased stress wave destructive–constructive interferences. Furthermore, the time interval between impacts is found to play a major role on the target's eventual ballistic performance. The oscillating phase caused by the excitation from the preceding impacting projectile, can amplify or diminish the relative impacting velocity of the subsequent projectile by as much as 40 %, resulting in either an over-perforation with residual velocity 55 % of the initial impacting velocity, or no-perforation with 0 % penetration depth.

Flexural Behavior of Corroded RC Beams Strengthened by Textile-Reinforced Concrete

The flexural behavior of corroded reinforced concrete (RC) beams strengthened with textile reinforced concrete (TRC) was analyzed and discussed in this work. Thirteen beams, including one reference beam, three corrosion-only beams, and nine TRC-strengthened corroded beams, were tested under four-point bending. The failure modes, cracks, bearing capacity, load–displacement curves and ductility of the tested beams were analyzed. The results showed that the TRC played a role in increasing the number of cracks and decreasing the width of the cracks in the corroded RC beams. In terms of improving the bearing capacity, TRC can improve the bearing capacity of corroded beams even more than the reference beams, and the strengthening after removing the concrete cover of corroded RC beams is better than direct strengthening. The corroded beams after TRC strengthening exhibited improved ductility. The energy absorption index of the TRC-strengthened corroded RC beams increased with the increase in the number of textile layers.

Mechanical, thermal insulation, and ablation behaviors of needle-punched fabric reinforced nanoporous phenolic composites: The role of anisotropic microstructure

Needle-punched fabric reinforced nanoporous phenolic composite (NPC) is a kind of promising ablative thermal protection material for spaceflight. However, in practical applications, typically anisotropic microstructure of NPC may lead to different performances and damage mechanisms under various directional mechanical or thermal loads. Herein, NPC is prepared and cut into specimens along three typical plane directions including XY-plane (0°), Z-plane (90°), and transitional-plane (45°), and their mechanical, thermal insulation, and ablation behaviors are systematically investigated. Benefiting from the woven fabric in XY-plane, NPC in 0°-plane direction exhibits highest tensile strength (169.2 ± 12.6 MPa), and CT image-based simulation further verifies that woven fabrics are primary load-bearing structure. Meanwhile, NPC in 45°-plane direction shows highest compressive strength (443.1 ± 18.2 MPa) but low compressive stress at low strain, demonstrating a weak bonding between two layers of woven fabrics. Moreover, the heat transfer simulation indicates that horizontally stacked woven fabrics effectively protect the internal material from thermal erosion, thus NPC in 0°-plane direction exhibits optimal thermal insulation. The ablation testing and micro-CT observations further demonstrate that the angle between woven fabric and thermal load significantly influences the ablation mechanism. The present work will further promote the structural reliability and optimization of needle-punched composites.

Optically transparent and high-strength glass-fabric reinforced composite

Fiber reinforced polymer composites (FRPs) are widely utilized in various industrial applications due to their significant advantages such as low cost and superior mechanical properties. However, owing to the trade-off between high mechanical strength and high optical transparency with typical FRPs, it is technically challenging to achieve high mechanical performance while meeting the optical requirements for transparent electronics and automotive applications. We herein report the synthesis of a transparent fiber reinforced polymer (tGFRP) by incorporating reinforced E-glass fiber into refractive-index-tunable thermosetting epoxy resin and the consequential advantageous opto-mechanical properties. By doping organic molecules, the optical property of the epoxy-based resin system has been efficiently engineered, achieving the match of the chromatic dispersions of the E-glass fiber and the epoxy resin. By the means of a novel technique derived from infusion treatment and in-situ polymerization combined with a liquid composite molding (LCM) method, both surface and bulk defects have been efficiently mitigated. With the refractive-index of the epoxy matrix matched with that of the embedded fiber fabrics, high transparency up to 88% has been realized with 10v.% fiber loading (500 μm thick tGFRP). An outstanding transparency and superior mechanical properties were achieved on 2 mm thick samples, maintaining up to 85% transmittance even when using 25 layers of E-glass fabric, corresponding to 50 v.% fiber. This work has shed light on the development of transparent composite materials for applications such as in construction, transportation, and protective equipment.

Об одном из подходов к прогнозированию и повышению шумопоглощения в кабинах транспортно-технологических машин

Noise is one of the main harmful production factors in the mining industry. The results of a hygienic assessment of working conditions indicate that exceeding the maximum permissible noise levels in 50 % of cases is recorded at the workplaces of drivers of the transport and technological machines. One of the efficient measures to reduce medium- and high-frequency noise in the cabins of transport and technological machines is the use of noise-absorbing upholsteries mounted on their metal panels. The article presents a computational and experimental procedure based on determining the reverberation coefficient of sound absorption of flat-sheet pressed samples of materials manufactured using the production technology of serial molded upholsteries. The material samples contained a base layer of open-cell polyurethane foam, a reinforcing layer of fiberglass, a thermally activated adhesive layer, a front layer of needle-punched fabric, and a back layer of non-woven fabric. The values were determined related to the sound absorption coefficient of flat-sheet pressed samples of materials manufactured using representative technology. The measurements were carried out with different sizes of air gaps relative to the reflective surface. As an example, the results of calculating the equivalent sound absorption area of the roof lining of a truck cab are considered. The obtained values of the equivalent sound absorption area for the original design option are below the target values for this part by up to 31 %. The original version was modified by changing the thickness of the molding of the blank and its location relative to the metal panel of the cabin without changing the material and design. As follows from the calculation results, the values of the equivalent sound absorption area of the roof lining in the modified version ensure that the target requirements are met.

Tetrapodal textured Janus textiles for accessible menstrual health

Menstruating individuals without access to adequate hygiene products often improvise with alternatives that pose health risks and limit their participation in society. We describe here a menstrual hygiene product based on low-cost materials, which are integrated onto fabrics to imbue unidirectional permeability. Abody-facing "Janus" fabric top layer comprising ZnO tetrapods spray-coated onto polyester mosquito netting imparts hierarchical texturation, augmenting the micron-scale texturation derived from the weave of the underlying fabric. The asymmetric coating establishes a gradient in wettability, which underpins flash spreading and unidirectional permeability. The hygiene product accommodates a variety of absorptive media, which are sandwiched between the Janus layer and a second outward-facing coated densely woven fabric. An assembled prototype demonstrates outstanding ability to wick saline solutions and a menstrual fluid simulant while outperforming a variety of commercially alternatives. The results demonstrate a versatile menstrual health product that provides a combination of dryness, discretion, washability, and safety.