A number of variations may include a method that may include providing a composite material that may include nano-tubes that may include pressure activated resin, forming the composite material such that the resin within the nano-tubes may begin to cure, holding the composite material in a formed state, removing the composite material from the formed state, and curing the composite material.

An architectural resin panel that incorporates plastic granules fused together to form a panel core. A portion of the plastic granules are contaminant granules that at least partially include a contaminant material, such as a piece of fabric, plastic film, or plant material. The granules used to form the panel core may be sourced from waste plastic material that would otherwise be required to undergo waste processing.

The disclosure relates to a method of fabricating a test socket including forming a plate-shaped first coupling block by joining a first base member made of a conductive material and a first insulating member made of an insulating material; forming a plate-shaped second coupling block by joining a second base member made of the conductive material and a second insulating member made of the insulating material; forming a first barrel accommodating hole for accommodating a part of the probe and a first support hole for supporting one end portion of the probe in the first coupling block; forming a second barrel accommodating hole for accommodating the rest of the probe and a first support hole for supporting the other end portion of the probe in the second coupling block; inserting one end of the probe into the first barrel accommodating hole to be supported on the first support hole, and inserting the other end of the probe into the second barrel accommodating hole to be supported on the second support hole; and joining the first coupling block and the second coupling block.

The present invention relates to a method of producing a cellulose-based product (103,700), wherein the method comprises the steps of: (i) providing at least two layers including one first (104a) and one second (104b) layer, and wherein said first (104a) and second layer (104b) each comprise cellulose fibers, and wherein at least one side of said first (104a) and/or said second (104b) layer is pre-treated with an adhesive coating, (ii) arranging said at least two layers including the one first (104a) and the one second (104b) layers in a superimposed relationship to each other in a forming mold (102) of a form press (101), thereby generating a stack (104) of said at least two layers including the one first (104a) and the one second (104b) layers, wherein said first (104a) and second (104b) layers are oriented within the stack (104) such that said at least one pre-treated side of said respective first (104a) and/or second (104b) layer is facing towards the superimposed layer, (iii) form pressing said stack (104) of at least two layers including the one first (104a) and the one second (104b) layers in a forming mold (102) at a forming temperature of at least 50 C. up to a forming end-pressure of at most 1100 MPa, into a cellulose based product (103, 700) of a predetermined shape and a single layer configuration, wherein in said step (iii) said layers including said one first (104a) and said one second (104b) layers are moveable with respect to each other until said forming end-pressure is reached.

A method for forming a composite sandwich structure by compression molding is disclosed. The method includes: placing a stack of two composite skins (13a, 13b) separated by a non-adherent layer (13c) in a compression molding tool (10); compression molding the stack of composite skins and non-adherent layer while applying heat to the tool, wherein compression molding of the stack is carried out until each composite skin conforms to and adhere to the molding surface adjacent to it but the thermoset resin in each composite skin is not fully cure; opening the compression molding tool, wherein each composite skin remains adhered to the adjacent molding surface; removing the non-adherent layer from the compression molding tool; placing a core layer (14) in the compression molding tool; and compression molding until the core layer is bonded to the composite skins, thereby forming a shaped sandwich structure (15).

A modified straw waste composite board and a preparation method thereof. The composite board sequentially comprises a surface layer, a substrate layer, a weight reduction layer, and a protective layer from top to bottom. The invention significantly enhances the comprehensive performance of composite boards by introducing innovative materials such as phosphorus-doped straw-based porous carbon, zinc oxide quantum dots, modified emulsified asphalt, and nano-silicon dioxide. Straw waste has abundant pore structures and excellent mechanical properties, which can improve the flame retardancy and mechanical properties of composite boards; zinc oxide quantum dots can extend the lifespans of composite boards; through scientifically designed components and advanced manufacturing processes, the invention solves the shortcomings of traditional boards, and achieves high-value utilization of agricultural waste, providing new ideas and technical support for the development and application of environmentally friendly composite materials.

A method of the present disclosure includes inserting thermoplastic components into a mold such that at least two or more thermoplastic components are adhered to an inner wall of the mold. The thermoplastic components are substantially hollow and made of a thermoplastic material. The method includes applying pressure onto the thermoplastic components adhered to the inner wall in a direction towards the inner wall of the mold to compress the thermoplastic components. The method includes heating the thermoplastic components concurrently with applying the pressure such that a first portion of the thermoplastic material of the thermoplastic components forms a first sheet on a first side of the thermoplastic components and a second portion of the thermoplastic material of the thermoplastic components forms a second sheet on a second side of the thermoplastic components opposite to the first side. The first sheet connects the plurality of thermoplastic components.

Particularly, proposed is a manufacturing method for a paper-made binding comb. The manufacturing method includes: providing a combined roll paper in which an inner roll paper and an outer roll paper are combined at a low-temperature by a low-temperature-sensitive molding material therebetween, the inner roll paper and the outer roll paper, each having a first side surface coated with a high-temperature-sensitive bonding material; slitting the combined roll paper at a predetermined width, and cutting the slitted roll paper such that the slitted roll paper has a comb part and a comb-connecting part, thereby forming a flat comb-shaped paper-binding piece; raising a temperature to the low-temperature such that only the low-temperature-sensitive molding material is melted; and transferring the flat comb-shaped paper-binding piece to a molding apparatus and molding the flat comb-shaped paper-binding piece into a cylindrical shape.