A vehicle having a space filling panel including a polystyrene layer, a polyurethane layer, and a polyethylene cover where the polyethylene cover forms a vacuum sealed space. The polystyrene layer and the polyurethane layer are both positioned in the polyethylene cover's vacuum sealed space. In another embodiment, a space filling panel for a vehicle includes a polystyrene layer comprising a plurality of polyurethane chips. The polystyrene layer having the plurality of polyurethane chips is enclosed in a vacuum sealed space formed by a polyethylene cover.

This invention relates to a method for forming a panel or skin for a hollow core door, a method of manufacturing a said door, a hollow core door, a panel, and an apparatus for forming a panel and skin for a hollow core door. The method comprises providing a substrate comprising a patterned groove therein; applying a laminating material on the substrate with an adhesive. The method then comprises sealing the substrate with the laminating material thereon in a chamber and providing at least one deformable membrane adjacent the laminating material; removing air from the chamber wherein under vacuum, the deformable membrane deforms into the groove thereby urging the laminating material into the groove; heating the laminating material to facilitate bonding thereof to the substrate; and allowing the substrate with the laminating material thereon to cool so as to form a panel with the laminating material bonded thereto.

A method is provided, for dissipating and entrapping super absorbent polymer particles (11, 12, 13, 14) within air-permeable, non-woven structures (100), for use in the construction of absorbent articles (600). The method comprises the steps of: (i) of constructing an air-permeable, non-woven structure (100) comprising at least first (1), second (2) and third (3) layers of non-woven fabric, each said layer having void spaces of differing size defined therein; (ii) dispersing absorbent particles (11, 12, 13, 4) onto an external surface (10) of the highest numbered layer of said air-permeable, non-woven structure (100) formed in step (i); and (iii) dissipating the dispersed absorbent particles (11, 12, 13, 14) within the air-permeable, non-woven structure (100) by applying an external energy source acting upon the absorbent particles (11, 12, 13, 14) in a direction substantially normal to the plane of the external surface (10) of the air-permeable, non-woven structure (100).

A method for laminating glass panels includes (1) providing a TFT substrate and a CF substrate to be laminated, in which the CF substrate is coated with a seal resin and the TFT substrate carries liquid crystal dropped thereon; (2) aligning and laminating the TFT substrate and the CF substrate in a vacuum environment to complete a lamination process; (3) applying UV light to transmit through the TFT substrate for carrying out UV curing of the seal resin interposed between the CF substrate and the TFT substrate so as to complete a UV curing process; and (4) removing the laminated CF substrate and the TFT substrate that have been subjected to the UV curing process out of the vacuum environment.

A vacuum bag sealing system may include a composite bagging sheet, and at least one interlocking strip connected to a surface of the composite bagging sheet, wherein the interlocking strip is configured to join a first section of the composite bagging sheet to a second section of the composite bagging sheet to form a sealed vacuum bag.

A laminate from which containers with improved transparency, high low-temperature impact strength and rigidity can be made. The laminate includes a resin layer [I] containing 60.0% by mass or more and 85.0% by mass or less of a propylene-based polymer (A) and 15.0% by mass or more and 40.0% by mass or less of an ethylene-based polymer (B), and a resin layer [II] containing 80.0% by mass or more and 99.9% by mass or less of a propylene-based polymer (A), 0.0% by mass or more and less than 15.0% by mass of an ethylene-based polymer (B), and 0.1% by mass or more and 20.0% by mass or less of a nucleating agent (C). The propylene-based polymer (A) and the ethylene-based polymer (B) satisfy specific requirements in both of the resin compositions [I] and [II].

A method is for manufacturing a honeycomb structure including a core material in which a hole is formed to penetrate in a thickness direction and is arranged in a plane direction, and a skin material that is stacked on a surface of the core material. The skin material includes a thermosetting resin. The method includes half-curing the thermosetting resin by placing the skin material in a bag and heating the skin material in a state where an inside of the bag is evacuated and an outside of the bag is under an atmospheric pressure; stacking the skin material in which the thermosetting resin is half-cured onto a side of the surface of the core material; and bonding and integrating the core material and the skin material with each other by pressurizing and heating the stacked core material and skin material with the use of a sealing pressurizing heating facility.

A lamination apparatus, system, and method. The apparatus, system and method are for a lamination press for laminating at least one laminating film to a subject, which may include: an upper press comprising a gel plate, an upper vacuum chamber, and tooling suitable to apply the laminating film; a lower press suitable to maintain the subject to receive the laminating film, and comprising a lower vacuum chamber, an air bearing stage, and servo-positioned tooling; and an aligner that applies the servo-positioned tooling to maintain positional balance and alignment of the subject by the air bearing stage during the laminating while enabling vertical flexure of the lower press, wherein the positional balance and alignment is substantially continuously monitored by a controller.

A method of manufacturing a stereoscopic image display device includes forming a groove by etching an edge portion of a rear surface of a lens array substrate, depositing a sticky material layer in the groove, disposed a transparent adhesive layer that differs from the sticky material layer onto a top surface of a display panel, aligning the lens array substrate and the display panel by using a camera, and joining the display panel and the lens array substrate by using the transparent adhesive layer.

A process for the production of manufactured articles in composite material comprises at least one supply phase of a plurality of layers and at least one coupling phase of the layers. The coupling phase comprises at least one step of arrangement of the layers overlapped onto each other to create at least one stratified body. The coupling phase comprises at least one step of positioning the stratified body inside a mould. The coupling phase comprises at least one firing step of the layers positioned inside the mould. The supply phase comprises at least one supply step of at least one basic layer and at least one supply step of at least one reinforcement layer.