A tissue fusion agent includes a particulate and/or fibrous flock material, wherein the fibrous flock material includes monofilament flock fibers and has a fiber length of 100 m to 3 mm. A discharge device can contain the tissue fusion agent and a surgical system can includes the tissue fusion agent or the discharge device and a tissue fusion instrument.

A method for manufacturing a textile product includes the steps of providing an intermediate product formed by a backing having a front surface and a back surface, and yarns applied into the backing, the yarns extending from the front surface of the backing material, feeding the intermediate product along a body having a heated surface, the back surface being pressed against the heated surface, to at least partly melt the yarns present in the intermediate product to form the textile product, wherein the part of the back surface that is pressed against the heated surface has a relative speed with respect to the heated surface, and a device enabling applications of this method and to a floor covering incorporating such a textile product connected to a dimensionally stable carrier sheet using thermo reversible covalent interactions.

A panel for absorbing mechanical impact energy includes a substrate and a multiplicity of fibers attached, by one of their ends, to the substrate with their other ends extending away from the substrate. The panel may include a thin, porous covering layer that overlies the free ends of the fibers. The porosity of the cover and the fiber density of the fibers may allow for breathability of the panel. The panels may be flexible and may be used in body protection devices such as helmets, body armor as well as in other environments. Panels may be configured in a variety of energy absorbing arrangements for differing applications.

A process and system for making a laminated surface covering and the surface covering itself are described. The covering includes several layers bonded to each other. The system performs the process. One example of the process includes passing a first material across a first conveyor, passing a second material across a second conveyor, passing a bonding material across a third conveyor, contacting the first material and the second material to the bonding material, and heating at least one of the first material and the second material. The process also includes introducing the first material, the second material, and the bonding material into a pressure zone such that the bonding material is introduced between a bottom surface of the first material and a top surface of the second material. The process applies pressure to bond the first material and second material together via the bonding material to produce a laminated material.

A method is provided for fabricating a construction (10) having a functional side (12). The method includes the steps of: supplying a flexible substrate (20); attaching one or more structures (30) to the substrate (20) on a surface or side thereof facing the functional side (12) of the construction (10); and forming one or more features, for example, such as fibrils (39), on at least one of the structures (30), wherein the features have at least one dimension which is at least one of micro-sized or nano-sized.

A method for manufacturing a textile product includes the steps of providing an intermediate product formed by a backing having a front surface and a back surface, and yarns applied into the backing, the yarns extending from the front surface of the backing material, feeding the intermediate product along a body having a heated surface, the back surface being pressed against the heated surface, to at least partly melt the yarns present in the intermediate product to form the textile product, wherein the part of the back surface that is pressed against the heated surface has a relative speed with respect to the heated surface, and a device enabling applications of this method and to a floor covering incorporating such a textile product connected to a dimensionally stable carrier sheet using thermo reversible covalent interactions.

The waterproof/breathable moisture transfer liner for alpine, snowboard and hiking includes an inner liner selected from technically advanced fabrics which are carefully selected. A series of layers are provided outside the inner liner including foam material and insulated nonwoven layers, breathable membranes, a supportive mesh included in a moldable foam, or moldable a spacer material and an outer shell fabric. The applicability of the liner to alpine boots, snowboard boots, cross country boots, hiking boots, protective gear, helmets, bouldering shoes, paddling apparel and gear along with appropriate variations for each application are disclosed.

A process and system for making a laminated surface covering and the surface covering itself are described. The covering includes several layers bonded to each other. The system performs the process. One example of the process includes passing a first material across a first conveyor, passing a second material across a second conveyor, passing a bonding material across a third conveyor, contacting the first material and the second material to the bonding material, and heating at least one of the first material and the second material. The process also includes introducing the first material, the second material, and the bonding material into a pressure zone such that the bonding material is introduced between a bottom surface of the first material and a top surface of the second material. The process applies pressure to bond the first material and second material together via the bonding material to produce a laminated material.

A method for manufacturing a textile product includes the steps of providing an intermediate product formed by a backing having a front surface and a back surface, and yarns applied into the backing, the yarns extending from the front surface of the backing material, feeding the intermediate product along a body having a heated surface, the back surface being pressed against the heated surface, to at least partly melt the yarns present in the intermediate product to form the textile product, wherein the part of the back surface that is pressed against the heated surface has a relative speed with respect to the heated surface, and a device enabling applications of this method and to a floor covering incorporating such a textile product connected to a dimensionally stable carrier sheet using thermo reversible covalent interactions.

The indoor or outdoor performance action sports product has a series of layers including a breathable, rapid dry, moisture transfer, thermal regulating performance comfort nonwoven insulation material, naturally adapting to temperature changes during active performance combined with a water resistant or waterproof fabric or material or a combination thereof. The performance action sports product may also include a series of layers including a breathable, rapid dry, moisture transfer, antimicrobial, performance nonwoven material wherein the fiber combinations provide extended comfort and performance with adjustable temperature regulation during indoor or outdoor performance.