Disclosed is a protective cover for an electronic device that is made from an elastomeric material that simultaneously provides cushioning that would otherwise be provided by a softer, thicker material, while utilizing a single, denser material that provides a slim profile and has sufficient density to conform well to the electronic device and prevent the transmission of impacts with hard surfaces directly to the electronic device. Although a denser material is used for the protective cover, recesses are formed in thicker portions at impact points that create compressible ribs. The ribs provide softer, cushioned portions of the cover in the impact areas, which are capable of absorbing the shock and energy of impacts.

The invention relates to a method for producing at least two-layer components and correspondingly produced components per se as absorptive lining in the interior and/or boot or for floor coverings of motor vehicles, comprising a top material and an absorber.

Provided is a method for producing a polyethylene-based resin extruded foam sheet by extruding and foaming a foamable molten resin composition formed by kneading a mixture containing a low-density polyethylene, a physical blowing agent, and an antistatic agent, wherein the foam sheet has a thickness in a range of from 0.05 to 0.5 mm, and the antistatic agent is a polymeric antistatic agent having a melting point whose different from the melting point of the low-density polyethylene is in a range of from 10 to +10 C., and having a melt flow rate of 10 g/10 min or more. This method enables a novel polyethylene-based resin extruded foam sheet to be obtained that is of high quality such that formation of a small hole or a through-hole has been reduced or eliminated, and has both excellent strength and a shock-absorbing property despite a very small thickness even in medium- or long-term continuous production, and besides, exhibits a sufficient antistatic property, thus suitable as a glass plate interleaf sheet.

A heating apparatus for an air cushion machine includes a hot sealing wheel, wherein a transmission wheel is respectively configured on two sides of the hot sealing wheel, an electrode plate is configured on an outer side of each transmission wheel, a guide cylinder seat is configured between the transmission wheel and hot sealing wheel, fixing guide cylinders are projected from the guide cylinder seat, the fixing guide cylinders are passed through the transmission wheel to be in electric contact with the electrode plate, heating sheets are configured inside the hot sealing wheel, each surface of the heating sheet is in electric connection with a conductive spring, another end of the conductive spring is configured with a carbon brush in rotational contact with the electrode plate, and the conductive spring and carbon brush are configured inside the fixing guide cylinder, thereby achieving high energy utilization, good temperature uniformity.

A surface underlayment system and its method of manufacture that is sandwiched between an impact-receiving upper surface and a lower foundation. The energy absorbing system has subassemblies of interconnected modules that cooperate to absorb and distribute impact forces applied thereto. Each module has one or more frustoconical support structures. At least some of the frustoconical support structures have bases that underlie the upper impact-receiving surface such as a golf putting green, a football field, marine decking, and senior living flooring.

Cushioning elements include a breathable material configured to allow gases to pass through at least a portion thereof, and a plurality of discrete segments of thermoplastic elastomeric gel (gel) heat-fused or otherwise attached to the breathable material. The gel comprises an elastomeric polymer and a plasticizer, with a plasticizer-to-polymer ratio of from about 0.3 to about 50. The plurality of discrete segments defines at least one breathable gap between adjacent discrete segments. Methods of forming cushioning elements include forming a plurality of discrete segments of gel, securing each segment to a breathable material, and providing a gas path through the breathable material and between adjacent segments. Another method includes providing molten gel within a mold, providing at least a second portion of the gel within a permeable material, and solidifying the gel to form discrete segments of gel.

A method for producing a product comprising a cup-shaped insert with a circumferential edge and a circumferential plastic body which is injection-molded onto the edge. The method includes: inserting the insert into a first mold of an injection molding tool; injecting a plastic melt into a first circumferential cavity formed by the first mold and the insert to produce a first circumferential plastic body part having a web which forms a recess; inserting the insert into a second mold of an injection molding tool, with the second mold designed such that a second circumferential cavity is formed on the edge region to be injection-molded to produce a second circumferential plastic body part; injecting a plastic melt into the second mold so that the plastic melt flows through the recess, fills the second cavity, and forms the second plastic body part; and removing the product from the mold.

A continuous sealing device includes: a first roller, having a first circumference, where the first circumference includes a first heat sealing segment; a first heating member, located at the first heat sealing segment, where when the first roller rotates, the first heating member bonds film sheets in a heat sealing manner to form a first bonding segment; a second roller, having a second circumference, the second circumference includes a second heat sealing segment; and a second heating member, located at the second heat sealing segment, where when the second roller rotates, the second heating member bonds the film sheets in a heat sealing manner to form a second bonding segment, and the first bonding segment and the second bonding segment are connected to form an uninterrupted heat sealing wire on the film sheets.

A sealing structure of an air-pocket bag machine includes at least one heating plate, a sealing roller that is rotatably mounted to and positioned against the heating plate for conducting a heating and pressing operation on and thus sealing at least one air-pocket bag through a heating operation of the heating plate, and at least one driving roller that is coaxially and rotatably coupled to the sealing roller for driving and advancing the air-pocket bag. With such an arrangement, when the air-pocket bag machine is activated, the air-pocket bag is driven by being in contact engagement with the driving roller and thus is moved to fast, stably, and continuously pass under the sealing roller. Due to the sealing roller and the driving roller being rotatably coupled in a coaxial manner, the advancing speed of the air-pocket bag is consistent with the rotational speed of the sealing roller.

The present invention provides high-density polyethylene (HDPE)/thermoplastic polyurethane (TPU) multilayered sheet, dunnage tray including HDPE/TPU multilayered sheet, methods of producing the same, and methods of recycling the same. The HDPE/TPU multilayered sheets described herein include functionalized HDPE. The methods described herein includes including co-extruding HDPE, functionalized HDPE and TPU, and optionally thermoforming the HDPE/TPU multilayered sheet. The HDPE/TPU multilayered sheets described herein have enhanced adhesion and peeling properties, as well as cold and impact resistance.