A multicomponent fiber having a shaped cross section is provided in this invention. The multicomponent fiber comprises: (A) at least one water dispersible polymer; and (B) a plurality of domains comprising one or more water non-dispersible polymers, wherein said domains are substantially isolated from each other by said water dispersible polymer intervening between said domains; and
wherein said water dispersible polymer is present at the perimeter of the outside cross-section of said multicomponent fiber in a proportion of not greater than 55% water dispersible polymer. Articles produced from the multicomponent fiber are also provided.

A process for making a multicomponent fiber is disclosed. The process comprises extruding at least one water dispersible polymer to create a first polymer flow, extruding at least one water non-dispersible synthetic polymer to create a second polymer flow path, directing the resulting multiple polymer flows into a spinneret having a shaped cross section with a plurality of distribution flow paths, and combining the flow paths together to form a multicomponent fiber having a shaped cross section, wherein the multicomponent fiber comprises: (A) at least one water dispersible polymer; and (B) a plurality of domains comprising one or more water non-dispersible polymers, wherein the domains are substantially isolated from each other by the water dispersible polymer intervening between the domains; and wherein the water dispersible polymer is present at the perimeter of the outside cross-section of the multicomponent fiber in a proportion of no greater than 55% water dispersible polymer.

A process for texturing a multicomponent fiber is provided. The process comprises: (A) providing a multicomponent fiber having a shaped cross section and at least one water dispersible polymer; and a plurality of domains comprising one or more water non-dispersible polymers, wherein said domains are substantially isolated from each other by said water dispersible polymer intervening between said domains; and wherein the water dispersible polymer is present at the perimeter of the outside cross-section of the multicomponent fiber in a proportion of no greater than 55% water dispersible polymer; and (B) passing the multicomponent fiber through a first zone comprising a first heating device and a twisting unit, wherein the first heating device has a heating temperature that is at least 10% less than the temperature used for a fiber without the water dispersible component having the same water non-dispersible polymer, same number of total filaments in the fiber, and the same total denier for a given type of equipment and process conditions.

A hemp hurd-based nonwoven material comprising a portion of hemp hurd and a portion of at least one other material; wherein the material is a natural or synthetic fiber selected from the group consisting of: polyester, nylon, polyethylene, polypropylene, cotton, flax, jute, ramie, bicomponent fibers, wood pulp, and other fibrous materials; and wherein the nonwoven material comprises between 1% and 99% hemp hurd.

A binding structure of an industrial fabric for binding both ends of a fabric with ends to form it into an endless type has loops formed by bending a portion or all ends of warp constituting the fabric at both ends and folding it back, the loop at the one end constitutes a binding loop which forms a common hole into which a core wire is introduced upon binding, the loop at the other end portion which is opposed to the binding loop to form a pair with the binding loop upon binding has a structure into which the binding loop is fitted and against which the binding loop is locked, and forms a loop hole into which the core wire is not introduced.

The presently disclosed subject matter relates generally to low thermal conductivity carbon materials and methods of producing the same. In some embodiments, the carbon materials are doped with low thermally conductive nanoparticles. In some embodiments, carbon fibers are prepared by electrospinning a mixture of polymers; and/or incorporating a low thermal conductivity additive, such as nanoparticles.

A detectable scouring pad is provided that is made with a sparse unwoven base polymer that defines the pad shape, an overcoating of cured thermoset resin loaded with a particulate on the base polymer, the particulate present in an amount to render the polymer detectable by X-ray detection or magnetometer detection. A process of detecting a scouring pad includes forming a fiber composed of a base polymer having a cross-section and a length, and distributing a particulate on the thermoplastic polymer in a thermoset resin matrix. The process further includes forming a sparse unwoven thermoplastic polymer from the fiber, and manufacturing the scouring pad from the sparse unwoven polymer by overcoating the base polymer with a particulate loaded thermoset resin. The scouring pad is passed through an X-ray detector or a magnetometer detector, and a signal is collected from the detector indicative of the presence of the scouring pad.

The current invention relates to a multitubular sheathing for electrodes of industrial batteries, which defines a plurality of longitudinal pockets receiving the terminals of an electrode inside, said sheathing being made of non-woven fabric formed from staple fibers made integral with one another, wherein the surface of said sheathing contacting said terminals exhibits a contact layer of non-woven fabric having at least 10% of fibers in a tangential direction. The invention further relates to a process for making said multitubular sheathing.

A heat spreading element is provided and includes first and second pyrolytic graphite sheets (PGSs) arranged to form an opening between respective proximal ends thereof and a weaved PGS. The weaved PGS includes a first section disposed above the first PGS, a second section disposed below the second PGS and a weaved section extending between respective proximal ends of the first and second sections and through the opening.

A woven sleeve includes a tubular member that includes circumferentially oriented fibers and axially oriented fibers. The tubular member is configured to adjust between a relaxed state in which the tubular member is positioned around a well tool and an extended state in which the tubular member is in tight contact with an outer surface of the well tool across substantially an entire inner surface of the tubular member to limit an extent to which the well tool can expand radially outward.