A method of manufacturing a multi-hardness and multi-elasticity foam mattress is provided, in which unit foam blocks made of polyurethane foams having multi-hardnesses and multi-elasticities are formed integrally with each other along the longitudinal direction of the foam mattress by the continuous foaming process to thereby mold a foam mattress. The foam mattress manufacturing method is simplified to increase the productivity of the foam mattress, and the durability of the foam mattress is excellent as well as the optimum body pressure distribution and somatotype maintenance effects can be implemented, and associated unit foam blocks of zones positioned symmetrically opposed to each other, based on a unit foam block positioned at the central portion of the mattress in the longitudinal direction of the foam mattress, have the same hardness and elasticity as each other.

The present invention is a composite material which can transfer heat very fast, for many applications such as car seat, wheelchair, stroller, apparel, medical care and therapeutic heating items. The present invention is a heating element to produce heat by applying a power supply, the heating element comprises of an interconnected mesh of a conductive filament deposits by a 3D printer on a non-woven fabric filler which acts as a thermal bed on the 3D printer to form a first layer, wherein the interconnected mesh of a conductive filament comprises of a combination of a plurality of parallel or series conductors with a plurality of connection nodes, and a double-sided adhesive lining to connect the first layer to a covering layer.

An assembly and method for steaming and/or heating a trim cover of an upholstered article is disclosed. The assembly includes a stand having a bottom end and a top end, an open frame attached to the top end of the stand and adapted to receive at least a portion of the trim cover, and a steam supply system. At least a portion of the steam supply system is adapted to fit within the frame and the steam supply system applies steam towards at least one interior steam zone of the trim cover.

Described is a machine for packaging mattresses comprising first movement means configured to move a mattress being processed along a first movement path and in a first feed direction and second movement means configured to move a functional layer along a second movement path and in a second feed direction. The second movement path is located at least partly above the first movement path until leading into it at a placement station, wherein the functional layer is placed on the mattress being processed. Means for applying adhesive material are positioned along the first movement path and detection means are configured and programmed to detect the position and preferably the dimensions of the mattress being processed and/or of the functional layer. The control unit is programmed to receive a detection signal indicating the position and preferably the dimensions detected and to generate a control signal of the first and/or second movement means.

A seat includes one or more cushions secured to a shell. The cushions include a 3D printed lattice of repeating cells. The cells may include nodes interconnected by branches. The nodes may be arranged in a cubic, parallelepiped, diamond, or other arrangement. The branches may extend directly between nodes or may be bent. The branches may extend from each node to an adjacent node that is closest to its point of attachment to the each node or the branches may be curved or bent to secure to a different adjacent node. The 3D printed lattice may include 3D printed barbs formed thereon that engage receptacles in the seat shell. The 3D printed lattice may be printed with a groove that engages a fastening structure on a cover or a separate fastening element. The cover may be a perforated sheet of material or fabric.

A padding device (10a; 10b; 10c; 10d; 10e), for a carrying belt system (100) for a respirator (1000), has a closed pad core shell (20) and a pad core (30) configured in the pad core shell. The padding device is formed by injection molding a hollow profiled section, inserting of a pad core material into the hollow profiled section for forming the pad core in the hollow profiled section, and closing the hollow profiled section (21) for creating the closed pad core shell (20). The padding device (10a; 10b; 10c; 10d; 10e) has a closed pad core shell (20) and a pad core (30) arranged in the pad core shell. The pad core shell is seamless as an injection-molded component in at least some sections. A carrying belt system and a respirator with the carrying belt system are provided with the belt system having the padding device.

Method for producing a seat for a vehicle, the bottom and the foam obtained by molding in a double mold by the following subsequent steps: gluing: in which a robot moves the molded product in front of a glue nozzle; activation: in which the robot transfers the molded product into a heating station, activating the glue; loading: in which a user arranges the cover in a loading station; superimposition: in which the cover is transferred into a superimposition station; simultaneously, a second robot grasps the molded product and moves it into the superimposition station; pressing: in which a plurality of grippers press the edge of the cover against the edge of the bottom, causing irreversible gluing between the bottom and cover, forming the seat; moving-away: in which the second robot grasps the seat from the superimposition station and places it on a conveyor belt to move it away.

A layered cushion that may be fully disassembled for easy cleaning is disclosed herein. The sleep system is durable and fire retardant. The layered cushion may include a foam layer, a layer of void cells, and a cover. The foam permits fluids to move freely there through and contours to a user's body to maximize comfort and reduce interface pressure. The reticulated foam layer resists compression set and thermosetting. The layer of void cells also permits fluids to move freely there through and provide additional support to the user's body. The individual void cells of the void cell layer are perforated to allow the transmission of fluids there through. The cover couples the other layers together to form the layered cushion and prevents the layers from deteriorating. The cover is removable to permit cleaning each of the layers independently.

A process manufactures a padding device (10a; 10b; 10c; 10d; 10e), for a carrying belt system (100) for a respirator (1000), having a closed pad core shell (20) and a pad core (30) configured in the pad core shell. The process includes injection molding a hollow profiled section, inserting of a pad core material into the hollow profiled section for forming the pad core in the hollow profiled section, and closing the hollow profiled section (21) for creating the closed pad core shell (20). The padding device (10a; 10b; 10c; 10d; 10e) has a closed pad core shell (20) and a pad core (30) arranged in the pad core shell. The pad core shell is seamless as an injection-molded component in at least some sections. A carrying belt system as well as a respirator with the carrying belt system are provided with the belt system having the padding device.

According to the present invention, in a plan view of a seat surface (10a), a plane area of a part surrounded by an inner edge (17a) of a rear part (17) in a left-right direction (X) and a contour (L) is larger than a plane area of a part sandwiched by an inner edge (18a) of a front part (18) in the left-right direction (X) and the contour (L) in the left-right direction (X). In addition, a part of a pair of left and right second synthetic resin materials forming a lower part having a maximum gap therebetween in the left-right direction (X) is positioned in a thigh rest part (14) and a part having a minimum gap is positioned in a hip rest part (15), and a maximum value (W1) of the gap between the pair of left and right second synthetic resin materials forming the lower part in the left-right direction (X) is two times or more a minimum value (W2) of the gap in the left-right direction (X).