A method for making composite structure with porous metal comprising: S20, providing a substrate; S30, fixing a porous metal structure on the substrate to obtain a first middle structure; S40, fixing at least one carbon nanotube structure on the porous metal structure in the first middle structure to obtain a second middle structure; and S50, shrinking the second middle structure to form a composite structure with porous metal.

A method for producing a composite component including a bottom layer, cover layer and honeycomb structure, including applying the honeycomb structure to the bottom layer wherein honeycomb chambers are formed. Honeycomb chambers are filled in a reinforcement region with a granular material and granular material is removed from other honeycomb chambers wherein each honeycomb chamber is filled up to a granular-material filling height and honeycomb chambers outside the reinforcement region are free of granular material. The cover layer is applied to the honeycomb structure wherein the honeycomb chambers are closed. The composite component is heated so the granular material in the honeycomb chambers expands to fill it with granular material and the cover layer, the bottom layer, the honeycomb structure and the expanded granular material harden, the density of the expanded granular material in the honeycomb chambers filled with granular material being dependent on the granular-material filling height.

An autonomous application machine installs screen protectors on mobile devices, such as cell phones. The machine has an enclosure with an interior. A cleaning station has a cleaning implement to contact a screen of the mobile device. A magazine carries a plurality of screen protectors. A lamination station has an applicator to place a screen protector from the magazine on the screen of the mobile device. A vision inspection station has a light source and a camera to initially visually inspect the screen of mobile device prior to cleaning in the cleaning station and to verify that the screen is undamaged and free of an existing screen protector; and subsequently visually inspect the screen protector on the mobile device after installation in the lamination station and to verify that the screen protector has been properly installed.

A method for producing a trim part includes the following steps: generating a surface covering, wherein a knitted semi-finished product is generated on a flat knitting machine; the knitted semi-finished product is washed; the washed knitted semi-finished product is heat set; and laminating, in particular press-laminating or compression-laminating, the generated surface covering onto a carrier part.

A production method for a high-pressure processed multilayer structure to be used for packages for foods and the like is provided. The production method includes: preparing a multilayer structure including an ethylene-vinyl alcohol copolymer (EVOH) layer formed from a resin composition containing an ethylene-vinyl alcohol copolymer having a saponification degree of greater than 99.7 mol % as a main component and an olefin resin layer having a thickness of less than 100 μm; and high-pressure processing the multilayer structure under a pressure of not lower than 200 MPa in an atmosphere at not lower than 20° C.

This disclosure relates a screen protector applicator that comprises a tray and two guide insert pins. The tray comprises a frame with an accommodating groove for accommodating a device, the frame includes two oppositely arranged long sides and two oppositely arranged short sides, surrounding the accommodating groove. Each guide insert pin comprises a connecting plate and a guide protrusion, wherein the connecting plate is slidably connected to the frame, the guide protrusion comprises a first protrusion, the first protrusion is fixedly connected to the connecting plate, the first protrusion is provided with a first inclined surface, the first inclined surface faces away from the accommodating groove, and the first inclined surface is inclined in a downward direction. With the above arrangement, two ends of a screen protector each can be gradually flatly attached to the device by pulling away the two guide insert pins.

A method of manufacturing a press pad is disclosed. The method includes: providing a planar pad having a first surface and a second surface opposite to the first surface and a release film sheet, the release film sheet including a polyimide-based film; cleaning the planar pad, the cleaning including electrostatically removing particulates from surfaces of the planar pad; and attaching a release film sheet to the first surface of the planar pad, the release film sheet being attached to the first surface using an acrylic-based adhesive containing thermoplastic polyolefin and methyl acrylate.

A method of manufacturing a press pad is disclosed. The method includes: providing a planar pad having a first surface and a second surface opposite to the first surface; cleaning the planar pad, the cleaning including electrostatically removing particulates from the first and second surfaces of the planar pad; and attaching a first release film sheet to the first surface and a second release film sheet to the second surface, the release film sheets being attached to the first and second surfaces using an acrylic-based adhesive containing thermoplastic polyolefin and methyl acrylate.

A filler material is applied to a plurality of wood elements. The plurality of wood elements is bonded into a composite wood product, where the bonding includes delivering ultrasound energy to the plurality of wood elements. The ultrasound energy has a frequency within a frequency range of 10 kHz-20 MHz.

The present invention belongs to the technical field of energy conversion devices, which provides an rGO-PEI/PVDF pyroelectric thin film, and the method for preparing the film, as well as a self-energized bracelet produced based on such film, which utilizes the reduced graphite oxide after modified by polyethyleneimine (PEI) (rGO-PEI) as photothermal conversion material, and the silver-plated polarized polyvinylidene fluoride (PVDF) film as pyroelectric conversion material. The rGO-PEI photothermal material is fixed to the surface of the PVDF through a transparent film, and prepare the self-energized bracelet based on it. The obtained bracelet has an output power of up to 21.3 mW/m2, and does not require additional mechanical devices to control the temperature during operation, wherein, the thermoelectric conversion, rectification, storage and application are realized through temperature fluctuation produced by absorbing sunlight during doing outdoor sports, utilizing temperature difference of air flow, and sweeping gesture, etc.