A high-speed cold laminating system including a cartridge having two rolls of pressure-sensitive laminating film. The goes into a receptacle of the laminating system. A steering module is upstream of the pressure rollers and a cutter is downstream of the pressure rollers. The steering module orients and positions sheets with respect to a directional path. The cutter severs a length of the laminating film containing a sheet from the remaining laminating film. A controller controls the conveyance of sheets and is programmed for bi-directional communication with an EEPROM of the cartridge. The EEPROM provides information to the controller regarding the laminating film, and the controller tracks film consumption within the system. The controller is programmed to periodically update the EEPROM of the laminating film cartridge with a current remaining film length during use within the laminating system based on the laminating film consumption tracked by the controller.

An arrangement step includes arranging a first glass substrate and a second glass substrate to make the first and second glass substrates face each other with a seal member interposed along multiple lines between themselves. A bonding step includes bonding the first and second glass substrates via the seal member. A cutting step includes cutting off the first and second glass substrates along an identical line as viewed in a direction in which the first and second glass substrates face each other and along the seal member. The cutting step also includes forming multiple sets of the first and second glass substrates divided by cutting off the first and second glass substrates along multiple lines where the seal member remains along respective sides of cross sections of the first and second glass substrates.

The method is used to manufacture lamination stacks (3) out of laminations (2) lying on top of one another which are cut out of a starting material (1) and are joined to one another using a radiation-activatable adhesive (4) within the lamination stack (3). The adhesive (4) is irradiated with radiation with a wavelength range below IR radiation for pre-activation. The installation used for this purpose has at least one application device for applying the adhesive (4) to a lamination (2). The adhesive (4) is irradiated with at least one radiation source (32) which emits radiation in a wavelength range below the infrared range.

A multilayer tube for a vehicle, a vehicle including a multilayer tube, and a method of forming a multilayer tube. The multilayer tube includes a liner of polyether ether ketone, which defines a bore in the multilayer tube. The multilayer tube also includes an exterior layer covering the liner. The exterior layer includes at least one polymer selected from a polyamide polymer, a polyphenylene sulfide polymer, a polyamide copolymer, and a polyphenylene sulfide alloy. The multilayer tube exhibits a continuous use temperature of 150 degrees Celsius or greater.

The invention relates to a mineral wool product comprising mineral fibers bonded by a cured binder wherein the binder in its uncured state comprises at least one protein and at least one enzyme.

A low-weight carpet tile and process for making the same, wherein the carpet tile comprises a facecloth having a plurality of face yarns tufted through a primary backing, an extruded polymer secondary backing layer, and a reinforcing scrim layer partially embedded within the extruded polymer secondary backing layer. The top surface and bottom surface of the carpet tile are defined by the facecloth and the reinforcing scrim layer, respectively. A polymer-based resin is extruded onto the facecloth to form an at least substantially uniform secondary backing layer, and the reinforcing scrim layer is laid onto the extruded polymer secondary backing layer while the extruded polymer secondary backing layer remains above a softening temperature for the resin. The entire multi-layer web is then passed through a nip to embed the reinforcing scrim layer into the extruded polymer secondary layer, and the entire web is chilled.

A film laminating apparatus and an electrode sheet processing device are disclosed. The film laminating apparatus includes a frame, a conveying mechanism, a mounting plate, and a plurality of film laminating mechanisms, the plurality of film laminating mechanisms being mounted on the mounting plate; the conveying mechanism being mounted on the frame and being capable of conveying an electrode sheet in a first direction into the film laminating apparatus; and the mounting plate being mounted on the frame and forming an included angle with the first direction. The plurality of film laminating mechanisms are tilted or vertically arranged relative to the conveying direction of an electrode sheet. The space occupied by the plurality of film laminating mechanisms, the size of the film laminating apparatus, the volume of the film laminating apparatus, and the space occupied by the film laminating apparatus in the conveying direction of the electrode sheet is reduced.

The present disclosure is an attachment configuration of decorative laminates comprising at least paired two decorative laminates attached to a base material. The at least paired two decorative laminates each have a double-sided adhesive tape adhered to an outer circumferential portion on a back side of the decorative laminate and a double-sided adhesive tape adhered to an inner portion inward of the outer circumferential portion to form a section. Elastic glue is applied to an outside of the double-sided adhesive tape for the outer circumferential portion on the back side. The elastic glue is also applied within the section formed with the double-sided adhesive tape for the inner portion. The at least paired two decorative laminates are fixed to the base material on their respective back sides while being spaced apart from each other.

The present disclosure relates to manufacturing an inflatable structure. There is determined one or more contours of at least a portion of an inflatable structure to be manufactured. There is further provided a drop stitch fabric having a first layer and a second layer tethered by drop stitches. Moreover, there is provided along at least a portion of the drop stitch fabric one or more fixation lines comprising coupling means fixating the first layer to the second layer, the one or more fixation lines corresponding to the one or more contours. Furthermore, the drop stitch fabric is coated, wherein one or more coating layers cover at least the one or more fixation lines. The disclosure also relates to an inflatable structure manufactured according to the foregoing, and a control system for controlling said manufacturing.

In a method for producing garments or bandages two superimposed fabric layers are interconnected by a dot-, line-, or areal elastomer connection wherein on one of the fabric layers a three-dimensional upstanding shaped part is formed by a layered application of an elastomer and is connected only to the fabric layer carrying the shaped part.