The present invention provides a moldable mixture containing large portion of agricultural fibers and small portion of a binding agent and a flow-promoting filler material. The moldable mixture is substantially free of formaldehyde, with low moisture content and high draw ratio. The present invention also provides methods of manufacturing molded products and related parts, based on the claimed moldable mixture. Molded products (830) and related parts such as runner (810) and plank (820) with light weight, high density and more complex profile are manufactured by the claimed methods including steps of providing required materials for a moldable mixture, mixing the provided materials to form a moldable mixture, shaking the moldable mixture in preparing for compression molding and compression molding the moldable mixture to form molded products and related parts.

A panel and a method for manufacturing thereof where the panel includes a first layer comprising a first blend of paper fragments and plastic fragments; a second layer comprising a second blend of paper fragments and plastic fragments, wherein the paper fragments and plastic fragments of the second blend are coated with an adhesive; and a third layer comprising the first blend of paper fragments and plastic fragments, wherein the second layer is disposed between the first layer and the third layer, and wherein the first layer, the second layer, and the third layer are combined to form the panel using heat and pressure. In another embodiment, the paper fragments and plastic fragments of the first blend, not the second blend, are coated with an adhesive.

The system comprises a grinder for crushing and pulverizing waste phenolic polymer material, wood fiber and porous material to form a powder; a homogenizer for mixing waste phenolic polymer material powder uniformly with resin for bonding the powder of the waste phenolic polymer material, wherein resin is added for bonding the powder of the waste phenolic polymer material, the powder of wood fiber and powder of porous material; a mixing chamber for mixing powder of waste phenolic polymer material, wood fiber and porous material uniformly; a pressing device for applying one of the methods of hot pressing, cold pressing, injection by an injection machine, extrusion by an extruder, or foaming of the obtained mixture to form desired solid material; and an analysis unit for determining a physical and mechanical properties of these boards using a series of tests such as compressive, tensile, flexural, thickness swelling, water absorption, and moisture content.

A method for providing container flooring for a container, including: providing a plurality of container flooring boards, each including a plurality of strand layers including strands of wood bonded together, at least a top strand layer and a bottom strand layer of the container flooring board having its strands substantially aligned in a first direction, and a dimension of the container flooring board in a second direction that is perpendicular to the first direction being selected to extend laterally between sides of the container in use; and arranging the container flooring boards inside the container, each container flooring board being positioned so that the strands of the top strand layer and the bottom strand layer are substantially aligned longitudinally relative to the container and the container flooring board extends laterally between the sides of the container, and respective edges of adjacent container flooring boards abut one another.

A system, controller, and method for decortication processing on one or more input units of hemp into one or more resultant products. The method includes: analyzing one or more characteristics of the input units; cutting the input units into a predetermined size; opening the cut input units; performing decortication on the opened input units to separate the hemp into components, the components including bast, fibre, and hurd; densifying the fibre into bales; pulverizing the hurd and bast; combining the pulverized hurd and bast with thermoplastic polymers into a resultant product; receiving analyzer data from at least one of the decortication, the densifying, the pulverizing, and the combining; training a machine learning model based on the analyzer data; using the trained machine learning model to adjust one or more aspects to achieve a desired resultant product.

A method for producing a veneered board having a veneer and a carrier board, to provide a veneered board having improved use properties. The method includes: providing a veneer having an upper face and a lower face, applying an additive onto the lower face of the veneer, applying a binder onto the lower face of the veneer, heating the binder, producing a stack of materials to be pressed, having a carrier board and a veneer provided with an additive and a binder on its lower face, wherein the lower face of the veneer lies on the carrier board, pressing the stack of materials to be pressed in order to form a veneered board.

A method of producing a board for production of panels is provided comprising: providing particulate material comprising or consisting of particulate wooden material, producing glued particulate material by applying an adhesive to the particulate material, forming a spreading material mat by homogeneously spreading the glued particulate material onto a conveyor on which the spread glued particulate material is conveyed in a conveying direction, and producing a board by pressing the spreading material mat. A reinforcement material is applied to the spread glued particulate material parallel to the conveying direction during forming the spreading material mat and/or after forming the spreading material mat before any pressing of the spreading material mat such that the spreading material mat has at least one longitudinal reinforcement zone containing the reinforcement material. Boards can be obtained from which panels can be produced which have reinforced longitudinal and/or transversal edges.

The present invention provides an energy-storing temperature control material, and belongs to the technical field of temperature control materials. In the energy-storing temperature control material provided in the present invention, the organic synthetic fiber based phase-change material has a three-dimensional dispersion effect, and can form a network constraint for remaining phase-change materials to reinforce mechanical properties of the materials, thereby fixing shapes of the materials and avoiding a liquid-crystal phase separation phenomenon in the phase-change process. The phase-change energy storage agent can absorb and release the heat by means of solid-liquid phase conversion of the material, to achieve the temperature control effect; and the phase-change temperature regulator can regulate a phase-change temperature range of the phase-change material, to make the energy-storing temperature control material suitable for climatic features of northern China.

A multi-layer fire-resistance treatment (FRT) panel for use as structural sheathing. The wood structural panel may be OSB or plywood, coated or treated during the manufacturing process with a product that provides fire resistance. The treatment may be integrated with the material forming the wood structural panel, or may be a coating layer applied to the mat or mat layer. A burn-through layer also may be applied. A protective layer comprising a resin-impregnated paper overlay may be applied on one or both sides of the panel.

A multi-layer fire-resistance treatment (FRT) panel for use as structural sheathing. The wood structural panel may be OSB or plywood, coated or treated during the manufacturing process with a product that provides fire resistance. The treatment may be integrated with the material forming the wood structural panel, or may be a coating layer applied to the mat or mat layer. A burn-through layer also may be applied. A protective layer comprising a resin-impregnated paper overlay may be applied on one or both sides of the panel.