The present invention concerns a reinforcing material comprising at least one fibrous reinforcement associated on at least one of its faces with a thermoplastic porous layer, said thermoplastic porous layer(s) representing at most 10% of the total mass of the reinforcing material, preferably from 0.5 to 10% of the total mass of the reinforcing material, and more preferably from 2 to 6% of the total mass of the reinforcing material, characterized in that said thermoplastic porous layer or each of said thermoplastic porous layers present comprises a so-called reactive thermoplastic polymer or consists of one or more reactive thermoplastic polymers, a reactive thermoplastic polymer carrying NH2 functions in an amount greater than 0.15 meq/g of reactive thermoplastic polymer and/or carrying COOH functions in an amount greater than 0.20 meq/g of reactive thermoplastic polymer.

The invention also concerns processes for manufacturing such reinforcement materials, preforms, processes for manufacturing composite parts and composite parts using such reinforcement materials.

The present invention concerns a reinforcing material comprising at least one fibrous reinforcement associated on at least one of its faces with a thermoplastic porous layer, said thermoplastic porous layer(s) representing at most 10% of the total mass of the reinforcing material, preferably from 0.5 to 10% of the total mass of the reinforcing material, and more preferably from 2 to 6% of the total mass of the reinforcing material, characterized in that said thermoplastic porous layer or each of said thermoplastic porous layers present comprises a so-called reactive thermoplastic polymer or consists of one or more reactive thermoplastic polymers, a reactive thermoplastic polymer carrying NH2 functions in an amount greater than 0.15 meq/g of reactive thermoplastic polymer and/or carrying COOH functions in an amount greater than 0.20 meq/g of reactive thermoplastic polymer.

The invention also concerns processes for manufacturing such reinforcement materials, preforms, processes for manufacturing composite parts and composite parts using such reinforcement materials.

A method for laying down a nanoweb of nanofibers from a centrifugal spinning process by a combination of an air flow field and a charging arrangement. Fibrous streams in the form of fibrils of molten polymer or polymer solution are discharged from a rotating member into an air flow field that is essentially parallel to the direction of discharge of fibrils at the point of discharge of the fibrils. The fibrous streams are attentuated and directed by means of the air flow field onto the surface of a collector to form a nanoweb. The fibrous streams are charged along all or at least a portion of their route from the point of discharge to the surface of the collector.

A method for laying down a nanoweb of nanofibers from a centrifugal spinning process by a combination of an air flow field and a charging arrangement. Fibrous streams in the form of fibrils of molten polymer or polymer solution are discharged from a rotating member into an air flow field that is essentially parallel to the direction of discharge of fibrils at the point of discharge of the fibrils. The fibrous streams are attentuated and directed by means of the air flow field onto the surface of a collector to form a nanoweb. The fibrous streams are charged along all or at least a portion of their route from the point of discharge to the surface of the collector.

A method for laying down a nanoweb of nanofibers from a centrifugal spinning process by a combination of an air flow field and a charging arrangement. Fibrous streams in the form of fibrils of molten polymer or polymer solution are discharged from a rotating member into an air flow field that is essentially parallel to the direction of discharge of fibrils at the point of discharge of the fibrils. The fibrous streams are attenuated and directed by means of the air flow field onto the surface of a collector to form a nanoweb. The fibrous streams are charged along all or at least a portion of their route from the point of discharge to the surface of the collector.

A method for laying down a nanoweb of nanofibers from a centrifugal spinning process by a combination of an air flow field and a charging arrangement. Fibrous streams in the form of fibrils of molten polymer or polymer solution are discharged from a rotating member into an air flow field that is essentially parallel to the direction of discharge of fibrils at the point of discharge of the fibrils. The fibrous streams are attenuated and directed by means of the air flow field onto the surface of a collector to form a nanoweb. The fibrous streams are charged along all or at least a portion of their route from the point of discharge to the surface of the collector.

Disclosed herein is a composition having a nylon polymer and tannic acid. The nylon polymer and the tannic acid are homogenously distributed in the composition. The composition may be made by dissolving a nylon polymer and tannic acid in a solvent to form a solution and removing the solvent from the solution to form the composition.

Disclosed herein is a composition having a nylon polymer and tannic acid. The nylon polymer and the tannic acid are homogenously distributed in the composition. The composition may be made by dissolving a nylon polymer and tannic acid in a solvent to form a solution and removing the solvent from the solution to form the composition.

A nonwoven web having a first web layer and a second web layer are disclosed herein. Methods of making such webs and absorbent articles including those webs are also disclosed. The first web layer has a core/sheath first composite fiber having a fiber fineness no greater than about 2.5 denier. The second web layer has a core/sheath second composite fiber having a fiber fineness no greater than about 2.5 denier and a homopolymer fiber having a fiber fineness of greater than about 3 denier. The homopolymer fiber is less than about 30% by weight of the second web layer.

Provided is a water absorbent laminate including: a first fiber layer including a first fiber assembly including first hydrophilic fibers; and a second fiber layer including a second fiber assembly including wet-heat-adhesive fibers in an amount greater than or equal to 80% by mass, wherein a surface of the first fiber layer on a side opposite to the second fiber layer has a water absorption rate less than or equal to 10 seconds as determined in accordance with the dropping method defined in JIS L 1907. Also provided is a method for producing the water absorbent laminate. The water absorbent laminate can further include a third fiber layer including a third fiber assembly including second hydrophilic fibers between the first fiber layer and the second fiber layer.