The soft boot and liner includes moisture transfer system that includes an inner fabric layer carefully selected from technically advanced fabrics. A series of layers are provided outside the inner liner including foam material layers, spacer fabrics and breathable membranes, in various orders. Encapsulation technology and waterproofing are used as well. The outer fabric layer is also capable of working with the other layers to promote the transfer of moisture. Frothed foams and flocking with fibers are further characteristics of the present invention. The moisture transfer system is incorporated into a soft boot or skate or as a removable liner for a shell boot. Numerous other modifications and applications are disclosed.

Provided is a dry cosmetic sheet including: a dry support formed of a mesh, the mesh being made of a woven silver yarn; and a dry membrane laminated on the support, the dry membrane being capable of being attached to a users skin, and the dry membrane being formed of a fiber web, the fiber web being formed of accumulated electrospun fibers, each of the electrospun fibers being formed of a single homogeneous mixture containing a water-soluble polymer, a water-insoluble polymer, and a functional material for skin care in a dry state, the functional material being capable of releasing from the fiber by dissolution of the water-soluble polymer when the dry cosmetic sheet is moisturized. Each of the electrospun fibers has a homogenous distribution of the water-soluble polymer, the water-insoluble polymer, and the functional material.

A sheet material is provided that includes a woven layer having a first side and an opposing second side, the woven layer formed from strand including a polyolefin polymer and a nucleating agent; a first polymeric coating disposed on the first side of the woven layer; and optionally a second polymeric coating disposed on the second side of the woven layer. The sheet material exhibits reduced thermal shrinkage.

An article comprises core of filler material, and a quilted textile enclosing the core wherein the textile comprises a first fabric having a cover factor between 70% and 95% and a tensile strength of at least 600 N/5 cm, the first fabric being a woven or knit fabric that is in contact with the core material, a second fabric bonded to the first fabric by an adhesive, the second fabric being a plush fabric, located on the side of the first fabric remote from the core, a first quilting yarn on the outer surface of the textile having a tenacity of at least 45 cN/tex and an elongation at break no greater than 10%, a second quilting yarn on the inner surface of the textile having a tenacity of at least 15 cN/tex and an elongation at break greater than 10%.

An RV ramp door is hingedly connected near the vehicle floor for selective opening and closing by a user. A weather-resistant construction of a ramp door includes an inner foam body having an inner face and an outer face, a ramp door inner surface, a ramp door outer surface, a first layer of thermoplastic composite material disposed between the inner face of the foam body and the ramp door inner surface, and a second layer of thermoplastic composite material disposed between the outer face of the foam body and the ramp door outer surface. The ramp door inner surface may be a slip-resistant material, and the ramp door outer surface may be a fiberglass panel. The ramp door may include one or more weep holes for releasing any trapped liquid.

A breathable and waterproof non-woven fabric is manufactured by a manufacturing method including the following steps. Performing a kneading process on 87 to 91 parts by weight of a polyester, 5 to 7 parts by weight of a water repellent, and 3 to 6 parts by weight of a flow promoter to form a mixture, in which the polyester has a melt index between 350 g/10 min and 1310 g/10 min at a temperature of 270° C., and the mixture has a melt index between 530 g/10 min and 1540 g/10 min at a temperature of 270° C. Performing a melt-blowing process on the mixture, such that the flow promoter is volatilized and a melt-blown fiber is formed, in which the melt-blown fiber has a fiber body and the water repellent disposed on the fiber body with a particle size (D90) between 350 nm and 450 nm.

Various embodiments of the teachings herein include a fiber material composite. The composite may include: a first region including metallic silver and manganese(IV) oxide for producing reactive oxygen species; and a second region configured to neutralize the reactive oxygen species.

Described is a composite made from a woven fabric, a non-woven fabric, or a knitted face fabric and a non-woven fabric. The woven fabric, the non-woven fabric, or the knitted face fabric is needle punched such that fibers protrude into the non-woven fabric. The woven fabric, the non-woven fabric, or the knitted face fabric has a first polymer having a first melting point and a second polymer having a second melting point being higher than the first melting point. The nonwoven backing material comprises a third polymer having a third melting point and a fourth polymer having a fourth melting point being higher than the third melting point. The woven fabric, the non-woven fabric, or the knitted face fabric is further bonded to the nonwoven backing material applying heat to at least partially melt or soften the first polymer and the third polymer such that they bond together.

A cloth mask includes a body, where the body has a piece of copper ion cloth and a piece of zinc oxide antibacterial cloth, the copper ion cloth is woven by a mixture of a first yarn, a second yarn and a copper yarn, the first yarn has a hydrophobicity and a moisture permeability and can form a water-resistant surface, and has a water-repellent effect and is exposed at an inner layer of the copper ion cloth, and the second yarn has a moisture-removing property and can form an antibacterial and moisture-removing surface to be exposed together with the copper yarn on a surface of the copper ion cloth.

A method of manufacturing a sandwich panel (100) includes: a step of preparing a plurality of sheet-like prepregs (211); a step of performing a first heating and pressurization process through a release film (25) on upper and lower surfaces of a laminate where the plurality of prepregs (211) are laminated such that the laminate is integrated to obtain a composite facing material (40); and a step of disposing the composite facing material (40) on each of an upper surface side and a lower surface side of a sheet-like core layer (10) having a honeycomb structure and integrating the laminate through a second heating and pressurization process, in which a pressure of the first heating and pressurization process is higher than or equal to a pressure of the second heating and pressurization process.