The present disclosure provides a flexible pressure sensor array and method for fabricating the same. The pressure sensor array comprises a pressure-sensing substrate, top electrodes and bottom electrodes. The pressure-sensing substrate comprises a piezoresistive material, a fabric and pressure-sensing columns. The top electrodes and the bottom electrodes are attached to the pressure-sensing columns. The pressure sensor array is ultra-flexible and conforms to 3-dimensional surface for pressure monitoring.

Systems, methods, and compositions for producing liquid repellant materials include a first support configured to support a spool of flexible substrate, a second support configured to support a plurality of compressing rollers configured to apply a force to a segment of the flexible substrate that extends from the roll. The segment is located within a zone between the compressing rollers. The system, in an embodiment, has a plurality of gas directors, wherein each one of the gas directors is configured to direct a stream of gas that flows at least partially around one of the compressing rollers. The streams cause an air pressure reduction in the zone. Also, the system has a precursor supply configured to expose the substrate to a precursor (e.g., a siloxane precursor), resulting in a coated material or protected material.

The present disclosure provides a flexible pressure sensor array and method for fabricating the same. The pressure sensor array comprises a pressure-sensing substrate, top electrodes and bottom electrodes. The pressure-sensing substrate comprises a piezoresistive material, a fabric and pressure-sensing columns. The top electrodes and the bottom electrodes are attached to the pressure-sensing columns. The pressure sensor array is ultra-flexible and conforms to 3-dimensional surface for pressure monitoring.

A fiber reinforced resin molded body; including: resin-integrated carbon fiber sheets 20 that are stacked and unified, each of the resin-integrated carbon fiber sheets 20 including a carbon fiber sheet 21 and at least one resin 23 selected from the group consisting of thermoplastic resin and thermosetting resin. The carbon fiber sheet 21 includes a unidirectional long-fiber group 21a spread and arrayed in one direction, and multidirectional fibers 22a and 22b derived from the unidirectional long-fiber group. The multidirectional fibers 22a and 22b cross carbon fibers constituting the unidirectional long-fiber group. The fiber reinforced resin molded body is a molded body of two or more stacked layers of the resin-integrated carbon fiber sheets 20, or a molded body of the resin-integrated carbon fiber sheet 20 that is stacked with a resin-integrated carbon fiber sheet including a different carbon fiber sheet. Thus, the present invention provides a fiber reinforced resin molded body including a surface-modified carbon fiber sheet and thus having high interlaminar fracture toughness, and a method for producing the carbon fiber sheet for the fiber reinforced resin molded body.

To provide a method of producing a processed cloth capable of forming various concave-convex patterns on a cloth material in a simple manner. A method of producing a processed cloth comprising the steps of: preparing a cloth; printing a first sizing agent containing a foaming agent on at least a portion of the cloth material; and pressing the printed cloth with a heated metal plate to foam the foaming agent. The method of producing a processed cloth may further include a step of printing a second sizing agent containing a coloring agent on the cloth material. The method of producing the processed cloth may further include a step of sublimation transfer to the cloth material.

A camouflage cover that is simple to deploy and store and is robust to all weather conditions and storage cycles provides a close visual match and close visible and IR spectral signature matches to surrounding vegetation. The cover incorporates a mixture of SAP and cellulose pulp containing approximately 90% water laminated between opaque, non-woven Tencel™ layers to emulate the spectral signature of leaves. Outer polymer film layers prevent water evaporation of the SAP. Organic dye-printed patterns can be applied to one or more of the Tencel™ and film layers. The SAP mixture can be limited to leaf regions of the cover, whereby branch regions include cellulose but not SAP. The cover can be petalized by cuts made, for example, along leaf and branch region boundaries. A gloss-controlling aerogel coating can be applied to outer surfaces of the camouflage cover to match a gloss of the vegetation.

According to various embodiments, a method of forming an image on a fabric and the resulting fabric is disclosed. The method includes providing a printable media including a carrier layer having a first surface comprising a first area and a second surface opposite the first surface. The method includes providing a fabric layer having a third surface and a fourth surface opposite the third surface, the third surface includes a second area. The fabric layer is secured to the carrier layer by the adhesive bonding a first portion of the fourth surface to the first surface. The method includes applying a toner to a first portion of the third surface of the fabric layer. The toner includes antimicrobial nanoparticles on an outer surface of the toner. The method includes fusing the toner to the first portion of the third surface of the fabric layer.

Socks or stockings including integrated gripping systems include gripping material disposed on external surfaces of a sole of the sock and gripping material disposed on internal surfaces of the sock. In some examples, the integrated gripping systems comprise a first set of gripping dots comprising gripping material applied to external surfaces of the sole of the sock and a second set of gripping dots comprising gripping material applied to internal surfaces of the sole of the sock. In some examples, the integrated gripping systems comprise a knitted fabric including gripping yarn, which includes knitted gripping portions disposed on internal surfaces of the sock and external surfaces of the sock.

Nonwovens having low-density and resilience have a chemical formulation applied on one surface (e.g., a top surface) by any of various application methods. Then, the chemical formulation is forced to move toward the opposite surface of the nonwoven (e.g., move downward through the nonwoven from top to bottom). The chemical-treated nonwoven is dried to fix the chemical on the nonwovens. Movement through the nonwoven is performed in a controlled fashion so that after drying the distribution of a chemical formulation throughout the nonwoven (e.g., from the top surface to the bottom surface of a nonwoven) is controlled.

Nonwovens having low-density and resilience have a chemical formulation applied on one surface (e.g., a top surface) by any of various application methods. Then, the chemical formulation is forced to move toward the opposite surface of the nonwoven (e.g., move downward through the nonwoven from top to bottom). The chemical-treated nonwoven is dried to fix the chemical on the nonwovens. Movement through the nonwoven is performed in a controlled fashion so that after drying the distribution of a chemical formulation throughout the nonwoven (e.g., from the top surface to the bottom surface of a nonwoven) is controlled.