The present disclosure provides a display substrate, a method for preparing the same, and a display device. The display substrate includes an insulating pattern whose surface layer is composed of a hydrophobic fluorine-containing material, so the organic ink used to prepare a light emitting layer does not overflow outside a pixel area. The method for preparing the display substrate includes: forming a rheological insulating material layer on the base substrate; curing the rheological insulating material layer, and patterning the cured insulating material layer to obtain an insulating pattern; heating the insulating pattern, to gather the hydrophobic insulating structure on a surface of the insulating pattern away from the base substrate; heating the gathered hydrophobic insulating structure to melt it, and then cooling the molten hydrophobic insulating structure to form a metal pattern on the surface of the insulating pattern.

The invention relates to a method for producing a printed nonwoven film laminate from a starting film web of a thermoplastic polymer material and a starting nonwoven web, wherein the melting point of the starting nonwoven web is above the crystallite melting point of at least one component of the polymer material of the starting film web. The method includes at least partially coating the starting film web with a printing ink and with an adhesion promoter; heating the coated film web together with the starting nonwoven web to a temperature which is above the crystallite melting point of the at least one component of the polymer material of the starting film web and of the adhesion promoter and below the crystallite melting point of the starting nonwoven web, to obtain a laminate; and cooling the laminate obtained through a cooled roller nip. Furthermore, the invention relates to printed nonwoven film laminates produced by the method and their use.

The invention relates to a method for producing a printed nonwoven film laminate from a starting film web of a thermoplastic polymer material and a starting nonwoven web, wherein the melting point of the starting nonwoven web is above the crystallite melting point of at least one component of the polymer material of the starting film web. The method includes at least partially coating the starting film web with a printing ink and with an adhesion promoter; heating the coated film web together with the starting nonwoven web to a temperature which is above the crystallite melting point of the at least one component of the polymer material of the starting film web and of the adhesion promoter and below the crystallite melting point of the starting nonwoven web, to obtain a laminate; and cooling the laminate obtained through a cooled roller nip. Furthermore, the invention relates to printed nonwoven film laminates produced by the method and their use.

Composite articles comprising a porous prepreg or core layer and a powder coated layer thereon are described. In some instances, a thermoplastic composite article comprises a porous core layer comprising a web of reinforcing fibers held together by a thermoplastic material, and a powder coated layer disposed on the porous core layer, in which a particle size of the powder coated layer is selected to provide an interface between the powder coated layer and the porous core layer, wherein at least 50% by weight of the disposed powder coated layer is present above the interface.

Composite articles comprising a porous prepreg or core layer and a powder coated layer thereon are described. In some instances, a thermoplastic composite article comprises a porous core layer comprising a web of reinforcing fibers held together by a thermoplastic material, and a powder coated layer disposed on the porous core layer, in which a particle size of the powder coated layer is selected to provide an interface between the powder coated layer and the porous core layer, wherein at least 50% by weight of the disposed powder coated layer is present above the interface.

Disclosed herein is a method of manufacturing an improved cover board product with a panel. In some embodiments, the method includes preparing fragments into an assembly; mixing the fragments and an adhesive into a blended core furnish; applying the adhesive to a top side of a bottom layer fabric in the assembly; forming a core mat of the blended core furnish on top of the adhesive; applying the adhesive to a top side of the core mat; applying a surface layer fabric on the top side of the adhesive; pressing the assembly; and cutting and trimming the assembly to form panels.

The present invention discloses a method and process to laminate packaging substrates using an adhesive tape. The tape has a first heat activated adhesive which is activatable at a first temperature and a second heat activated adhesive which is activatable at a second temperature and both of which are alternatively coated on at least one surface of the tape. The method consists of laminating this aforementioned tape to a packaging substrate by following the process of: placing this tape in or on a laminating machine over the packaging substrate, heating the tape at least to the second temperature while making contact with the packaging substrate, cooling the packaging laminate until the second heat activated adhesive is set and cutting a predetermined portion of the packaging laminate before a second adhesive occurs between the tape and the packaging laminate.

The present invention discloses a method and process to laminate packaging substrates using an adhesive tape. The tape has a first heat activated adhesive which is activatable at a first temperature and a second heat activated adhesive which is activatable at a second temperature and both of which are alternatively coated on at least one surface of the tape. The method consists of laminating this aforementioned tape to a packaging substrate by following the process of: placing this tape in or on a laminating machine over the packaging substrate, heating the tape at least to the second temperature while making contact with the packaging substrate, cooling the packaging laminate until the second heat activated adhesive is set and cutting a predetermined portion of the packaging laminate before a second adhesive occurs between the tape and the packaging laminate.

This invention generally relates to a method of manufacturing hybrid parts comprising metallic and non-metallic materials at high temperature. During the method, a hollow metallic feedstock heated to a temperature in the austenite region may be placed in a die and filled with a non-metallic material in a viscous condition, after which the feedstock in the die is formed and then controlled-cooled to cause hardening of the non-metallic material in the region of contact between the metallic and non-metallic material. Afterwards, the semi-finished product is removed from the die and cooled to room temperature. The rate of cooling may be adjusted to generate compressive stress in the surface layer of the non-metallic material, which reduces the risk of cracking.

This invention generally relates to a method of manufacturing hybrid parts comprising metallic and non-metallic materials at high temperature. During the method, a hollow metallic feedstock heated to a temperature in the austenite region may be placed in a die and filled with a non-metallic material in a viscous condition, after which the feedstock in the die is formed and then controlled-cooled to cause hardening of the non-metallic material in the region of contact between the metallic and non-metallic material. Afterwards, the semi-finished product is removed from the die and cooled to room temperature. The rate of cooling may be adjusted to generate compressive stress in the surface layer of the non-metallic material, which reduces the risk of cracking.