A cooling material is provided. The cooling material can include a yarn having a defined denier of less than or equal to approximately 90 denier, wherein the yarn can comprise a cooling additive disposed on or in a polymer. In some embodiments, the yarn can be at least one of a warp or a weft of a woven fabric. A method can comprise receiving a cooling material, wherein the cooling material comprises: a polymer and a cooling additive, wherein the cooling additive is disposed on or in the polymer; and processing the cooling material by employing a non-weaving technique to create a non-woven fabric. In some embodiments, the non-weaving technique is one of a meltblown process, a spunbond process, or a multi-denier process.

A mattress pad for supporting a human body includes an upper layer, a lower layer, and a wadding layer therebetween. The wadding layer includes three distinct zones arranged along the length of the pad for varying support of the human body. The first zone is configured to support a head portion and a neck portion; the second zone is configured to support an upper body portion and a lumbar portion; and the third zone is configured to support a lower back portion and leg portion. Thickness and length in these zones varies for providing the varying support.

To produce a seat cushion body, at least one yarn is cut to produce a fiber material. The fiber material is transported from a cutter system which cuts the at least one yarn to a mold.

An object is to provide a hygienic cushion that has an adequate thickness to provide the repulsive force of or above a specified level and the body-holding property, is light in weight, has excellent air permeability and is washable with water. The core material for cushion 1 comprising the three-dimensional net-like structure, which is comprised of a polyethylene thermoplastic resin, a polyester thermoplastic elastomer or a mixture of a polyethylene thermoplastic resin and a polyethylene thermoplastic elastomer. The three-dimensional net-like structure has a first layer that includes a thermoplastic resin and a second layer that is stacked on a single surface or both surfaces of the first layer and includes a thermoplastic resin different from the thermoplastic resin of the first layer. The three dimensional net-like structure has an impact resilience of not lower than 13 cm, a hysteresis loss of not higher than 34% and not lower than 13%, and a thermal expansion rate of 0 to 8% in the longitudinal direction before and after a hot-air drying test that is performed at a temperature of 90 C. for 30 minutes with regard to the polyethylene thermoplastic resin, that is performed at a temperature of 130 C. for 30 minutes with regard to the polyester thermoplastic elastomer and that is performed at a temperature of 90 C. for 30 minutes with regard to the mixture of the polyethylene thermoplastic resin and the polyethylene thermoplastic elastomer.

An osmosis membrane is disposed at the boundary between a three-dimensional network structure section and a foam section. The osmosis membrane allows a liquid foam material to permeate. The three-dimensional network structure section is impregnated with the foam material through the osmosis membrane, and subsequently the foam material is solidified, thereby connecting the three-dimensional network structure section and the foam section to each other. The bonded body of the three-dimensional network structure section and the foam section is completed only by disposing the cushion structure component in between the upper mold and the lower mold, and performing a foaming step.

A mattress containing a core section, a high loft non-woven layer at least partially covering a first side of the core section and containing a plurality of heat and flame resistant fibers, bulking fibers, and binder fibers, a ticking layer at least partially covering the high loft non-woven layer and containing a textile layer, a pattern coated layer. The pattern coated layer may be printed on the high loft non-woven layer, the ticking layer, or any layer between the high loft non-woven layer and the ticking layer. The pattern coated layer contains a blend of microencapsulated phase change material (PCM) and a binder, wherein the PCM is fully encapsulated by the binder.

Provided are an inflatable structure, an inflatable product, and a method for manufacturing for an inflatable product. The inflatable structure comprises a first layer and a second layer; a composite material comprises a plurality of filling materials which are sequentially stacked from top to bottom; a reflective layer is arranged between a pair of adjacent filling materials; an upper end of the composite material is connected to the first layer, and a lower end of the composite material is connected to the second layer. The composite material is arranged between the first layer and the second layer of the inflatable structure, and said composite material is respectively stretched by the first layer and the second layer; the stretched filling materials are attached to upper and lower surfaces of the reflective layer like two spring structures; when external vibrations are transmitted to the reflective layer, said vibrations are dampened.

A hybrid mattress includes a plurality of layers, comprising a top portion predominantly formed of one or more foam layers, which may be of the same or different types, and a bottom portion comprising 50% to 100% vertically lapped nonwoven material layers. The top surface layer of the plurality of layers may be a thin chemically treated vertically lapped nonwoven material.

A mattress assembly includes a cover, a spring pack positioned within the cover, and an inner core positioned within the cover. The inner core includes opposite first and second portions. The first portion has a firmness that is different than a firmness of the second portion. The inner core is configured to be moved between a first configuration in which the first portion directly engages the spring pack and a second configuration in which the second portion directly engages the spring pack to alter a firmness of a sleep surface of the mattress. Methods of use are disclosed.

The present invention relates to the technical field of mattresses, and particularly provides a high-elastic anti-deformation mattress. The high-elastic anti-deformation mattress includes a mattress assembly which includes a first layer, a second layer and a third layer from top to bottom in a sequence; a plurality of assembling chambers are formed in the second layer, and each assembling chamber is filled with a vertically upward spring; a large-diameter end of each spring is upwards close to a top portion of the corresponding assembling chamber, and a small-diameter end of each spring is downwards connected to a top surface of the third layer; a connecting base is inserted into a large end of a top portion of each spring; reinforcing nets are mounted among all the connecting bases, and the peripheries of the reinforcing nets are close to the peripheries of the first layer and the second layer.