A three-dimensional striped structure is provided which is formed by bonding continuous filaments in random in loops, has a longitudinal direction corresponding to an extruding direction, a lateral direction and a thickness direction perpendicular to the extruding direction, and 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 striped 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, and does not shrink during high-temperature sterilization.

This disclosure describes, among other things, techniques for waking a user by changing the user's sleep environment. In one example, a method includes receiving, at a central controller of an air mattress system, at least one user alarm setting, generating, via the central controller, at least one instruction based on the received user alarm setting, and transmitting, from the central controller, the at least one instruction to a first component of the air mattress system to adjust a feature of the first component.

This disclosure describes, among other things, techniques for waking a user by changing the user's sleep environment. In one example, a method includes receiving, at a central controller of an air mattress system, at least one user alarm setting, generating, via the central controller, at least one instruction based on the received user alarm setting, and transmitting, from the central controller, the at least one instruction to a first component of the air mattress system to adjust a feature of the first component.

The present invention relates to a mat production apparatus for producing a multifunctional mat. The mat production apparatus includes: a transfer printing device including a guide unit configured to introduce a multifunctional mat and transfer paper, a first heating panel configured to include an aluminum heater panel so that transfer printing can be performed, a first manifold configured to distribute heat, a transfer means disposed below the first manifold and configured to perform transfer printing on the multifunctional mat through thermal bonding without pressure, and a first elevation means configured to selectively elevate and lower the transfer means; and a processing device including a mat seating part configured such that the transfer-printed multifunctional mat is seated thereon and a processing panel disposed above the mat seating part and configured to perform thermal bonding so that folding grooves and edges can be formed on the multifunctional mat.

The present application provides a cushion having a core layer and a quilt support/comfort layer. The core layer may comprise innersprings, foams, air cells, or combinations thereof. The support/comfort layer comprises a sleep layer that simulates a conventional quilted fabric layer. The sleep layer includes a thick, comfort fabric and a backing fabric, which backing fabric may be the same as the thick, comfort fabric. The sleep layer is formed by coupling the thick, comfort fabric to the backing fabric to form a plurality of individual pockets in which micro spring coils are placed. The micro spring coils have less uncompressed height than conventional innerspring coils. The sleep layer coupling is formed by spot coupling without using a metal needle to stitch the layers together. In other words, the spot coupling may comprise an adhesive or weld.

A three dimensional polymeric fiber matrix layer for use in a bedding product such as a mattress is disclosed. The three dimensional polymeric fiber matrix layer generally includes a plurality of randomly oriented polylactide (PLA) fibers bonded at coupling points between adjacent PLA fibers and having a free volume per unit area of the layer.

A pre-conditioned three dimensionally polymeric fiber matrix layer for use in a bedding product such as a mattress is disclosed. The pre-conditioned three dimensionally polymeric fiber matrix layer generally includes an extruded three dimensional polymeric fibrous layer and a foam material, e.g., polyurethane, latex or the like, disposed within the fibrous layer and occupying at least a portion of the free volume in the layer, wherein a portion of the coupling points and the randomly oriented polymer fibers are broken so as to change a mechanical property of the pre-conditioned three dimensionally polymeric fiber matrix layer relative to the three dimensionally polymeric fiber matrix layer without pre-conditioning.

A three dimensional polymeric fiber matrix layer including a phase change material coated thereon for use in a bedding product such as a mattress is disclosed. The phase change material is selected to provide improved cooling properties, which along with the free volume provided by the three dimensional polymeric fiber matrix markedly improves temperature management when used in a bedding product.

A system and a method for adjusting a bed are disclosed. The bed is preset with a plurality of sets of adjustment parameters. An external muscle strength/pressure detection device or method is used to select at least two sets of the adjustment parameters suitable for the user. The corresponding sleep parameters are detected when the user sleeps, and the user-specific adjustment parameters are quickly selected and sent back to the bed for adjustment. Through the method, there is no need for the bed to provide pressure sensors.

This disclosure describes, among other things, techniques for waking a user by changing the user's sleep environment. In one example, a method includes receiving, at a central controller of an air mattress system, at least one user alarm setting, generating, via the central controller, at least one instruction based on the received user alarm setting, and transmitting, from the central controller, the at least one instruction to a first component of the air mattress system to adjust a feature of the first component.