The present invention relates to a nano thin-film transfer sheet comprising a permeable base, a soluble support layer, and a nano thin-film layer in this order, wherein the permeable base is a base which allows a solvent dissolving the soluble support layer to permeate or penetrate therethrough.

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.

A laminate includes: a semiconductor substrate; a light-transmissive support substrate; and an adhesive layer and a release layer disposed between the semiconductor substrate and the support substrate. The release layer is formed of a release agent composition containing a compound having: a first structure that absorbs the light and contributes to facilitating the semiconductor substrate and the support substrate to be released by absorbing the light; and a siloxane structure as a second structure.

The present disclosure belongs to the technical field of three-dimensional packaging, and in particular relates to a bonding method for a copper-copper metal. The bonding method includes: subjecting a copper-plated surface of a clean copper-plated substrate to pretreatment with hydrazine hydrate under a protective atmosphere, to obtain a copper-plated substrate to be bonded, where the copper-plated surface is kept at 50? C. to 90? C.; and subjecting a plurality of the copper-plated substrates to be bonded to pressurized bonding at 200? ? C. to 300? ? C. under the protective atmosphere.

A method of segmenting a cured NdFeB magnet includes providing a first and a second NdFeB magnet. The surface of the NdFeB magnets is cleaned. An insulating adhesive is deposited on the surface of the first NdFeB magnet. Then, the first NdFeB magnet is cured. Next, a layer of the insulating adhesive is deposited on the surface of the NdFeB magnets. Then, the first NdFeB magnet and the second NdFeB magnet are stacked to produce a stacked NdFeB magnet. After stacking, a predetermined clamping pressure is applied to the stacked NdFeB magnet. The stacked NdFeB magnet is then cured to produce a cured NdFeB magnet. The cured NdFeB magnet is then machined into a plurality of small NdFeB magnets. The step of depositing the insulating adhesives is further defined as depositing a plurality of beads of the insulating adhesive onto the surface of the first NdFeB magnet.

An manufacturing method of an electronic device includes: providing a first substrate and a second substrate; attaching an adhesive member onto the first substrate; and performing a curve attaching step, so that the first substrate and the second substrate are attached to each other through the adhesive member to form a curved composite component, wherein the curve attaching step is performed at a temperature of 20 degrees Celsius to 160 degrees Celsius.

In one example, a metal-plastic composite structure for an electronic device is described, which includes a micro-arc oxidized metal substrate and at least one plastic film disposed on the micro-arc oxidized metal substrate using a superplastic forming process.

A method for making a coated fabric includes the steps of: applying a coating solution of a resin in an organic solvent to a roller-conveyed non-stretchable and releasable substrate web to form a coating layer; laminating a roller-conveyed base fabric to the coating layer to form a laminate; guiding the laminate to pass through at least one tank containing water to immerse the laminate in water such that the coating layer is solidified and the organic solvent contained in the coating layer is replaced by water; and removing water from the coating layer by drying to leave micropores in the coating layer.

A roofing system may include a first ethylene propylene diene terpolymer (EPDM) roofing membrane having a first lap. The roofing system may include a second EPDM roofing membrane having a second lap that overlaps at least a portion of the first lap of the first roofing membrane. The roofing system may include a thermoplastic film positioned between the first lap and the second lap. The thermoplastic film may bond the first lap and the second lap together.

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.