An active-insulation paneling component and garments including an active-insulation paneling component. The active-insulation paneling component includes insulated panels separated by gussets. The gussets are configured to expand upon an outward pulling force to allow the active-insulation paneling component and/or garment to expand even where the active-insulation paneling component and/or garment are not manufactured from elastic materials.

An active-insulation paneling component and garments including an active-insulation paneling component. The active-insulation paneling component includes insulated panels separated by gussets. The gussets are configured to expand upon an outward pulling force to allow the active-insulation paneling component and/or garment to expand even where the active-insulation paneling component and/or garment are not manufactured from elastic materials.

An active-insulation paneling component and garments including an active-insulation paneling component are disclosed. The active-insulation paneling component includes insulated panels separated by gussets. The gussets are configured to expand upon an outward pulling force to allow the active-insulation paneling component and/or garment to expand even where the active-insulation paneling component and/or garment are not manufactured from elastic materials.

A patch comprising a lower layer of felt material, and an inner area stitched to the felt and having a desired shape. A first stitched border surrounds the central area, and a second stitched border surrounds the first border.

The present invention relates to a polymer having a first monomer selected from the group consisting of: styrene, MMA, HEMA or MEMA and a second monomer selected from the group consisting of: GMA, DEAEA, DEAEMA, DMAA, BAEMA, 4-vinylpyridine, DMVBA, 1-vinylimidazole, DMAEA or a combination thereof as coating agent for a scaffold or a medical device, to promote cellular adhesion and/or cell growth or for the manufacture of yarns or threads. The polymer may further contain a third monomer selected from the group consisting of: BMA, DEGMEMA, DAAA and MMA. The invention also relates to a scaffold, a medical device, a yarn, a thread or a textile coated or manufactured with the polymers of the invention and relative methods.

A system of fabric-based devices designed as transistors with tri-state behavior that can measure any geometries on 2D and 3D surfaces. The devices are constructed from layers of conductive materials and flexible sheets that allow signals to selectively cross between layers. Multiple layers of conductive signals can be achieved by controlling the tension of the top and bottom thread, and interlayering conductive, semiconductive, insulating, and semi-porous materials around a sensing layer. The layers can be further modified to include folds and cuts that allow for 2D and 3D bending, stretching, twisting, and curves. Large sheets of devices can be organized into grid-like matrixes, with signal wires connected in a multiplexed fashion to minimize the amount of threads to simplify construction and device communication to a central processing unit.

A system of fabric-based devices designed as transistors with tri-state behavior that can measure any geometries on 2D and 3D surfaces. The devices are constructed from layers of conductive materials and flexible sheets that allow signals to selectively cross between layers. Multiple layers of conductive signals can be achieved by controlling the tension of the top and bottom thread, and interlayering conductive, semiconductive, insulating, and semi-porous materials around a sensing layer. The layers can be further modified to include folds and cuts that allow for 2D and 3D bending, stretching, twisting, and curves. Large sheets of devices can be organized into grid-like matrixes, with signal wires connected in a multiplexed fashion to minimize the amount of threads to simplify construction and device communication to a central processing unit.

A patch comprising a lower layer of felt material, and an inner area stitched to the felt and having a desired shape. A first stitched border surrounds the central area, and a second stitched border surrounds the first border.

The present invention relates to an alignment jig for aligning leather sheet and a Velcro structure before sewing to couple the leather sheet and the Velcro structure which form a vehicle seat cover. The guide part having the accommodation groove into which the Velcro structure can be inserted and fixed is formed on the lower plate of the alignment jig, and the penetration part is formed in the upper plate thereof. Accordingly, after the Velcro structure is inserted and fixed into the accommodation groove of the guide part, when the leather sheet is placed thereon and the upper plate is closed, the leather sheet and the Velcro structure are aligned automatically, and then, when sewing is performed through the penetration part of the upper plate, the Velcro structure can be accurately aligned and coupled on a predetermined curved path of the leather sheet.

A system of fibers, filaments, and/or other electrically conductive materials forms an electrically conductive-to-semi-conductive yarn that can be assembled into a textile for measurement of voltage, current, resistance, capacitance, inductance, RF, and/or EM signals. Textiles are formed through weaving, knitting, lacing, and/or non-woven mechanical methods of yarn-making into 2D/3D structures. Textile-based electrodes can be formed via folding, cutting, layering, sewing, and/or embroidering patterns to control signal transmission within/through the electrode. Multiple electrodes are positioned on a surface (e.g., a body) to sequentially or simultaneously perform multiple diagnostic modalities (e.g., electrocardiography, electromyography, electrooculography, electroencephalogram, bioelectrical impedance analysis, skin impedance analysis, and/or electrodermal activity). These modalities are multiplexed using an optimized electrode set through amplitude and frequency deconvolution and filtering algorithms to minimize the quantity of electrodes and connections on the surface while maximizing signal-to-noise ratio, differential and common mode noise rejection, and elimination of external signals (e.g., RF and EM noise).