An absorbent pad has: a first, outer layer comprising a permeable or non-permeable film; a second, outer layer comprising a permeable or non-permeable film, placed on a side of the pad opposite the first, outer layer; a third layer disposed between the first layer and the second layer, and comprising a tissue laminate comprising at least a first ply and a second ply, with at least one chemical agent or system fixed in the third layer and being either activated by contact with or soluble in an aqueous liquid, the at least one chemical agent or system being in a predetermined amount distributed substantially uniformly per unit area of the surface area between the at least first ply and second ply: and a fourth layer disposed between the first layer and the second layer and comprising fluff, with or without a chemical agent or system, the third layer being joined to the fourth layer to serve as a substrate for the fourth layer.

The present disclosure relates to a hollow board 1 with first and second main surface layers 3, 5. A plurality of distance elements connecting the first and second main surface layers and maintain a predetermined distance there between. The main surface layers include at least a layer of high-density fiber, HDF, board, and a plurality of distance elements are distributed in the space between the main surface layers, and at least some comprise at least one elongate HDF board strip 15 which is oriented such that its longitudinal edges interconnect the first and second main surface layers 3, 5. The HDF boards of the surface layers and of the at least some of the distance elements comprise wood particles bonded by a resin including an isocyanate, such as methylene diphenyl di-isocyanate, MDI.

The present invention relates to a reconstituted wood panel, and more particularly to a reconstituted wood panel with natural wood grain and manufacturing method thereof. The reconstituted wood panel with natural wood grain of the present invention is manufactured by peeling or slicing the logs to obtain veneers with thickness of 320 mm, and then impregnating with adhesive and hot pressing. The compression ratio is 10%, and the density is 0.71.3 g/cm3, and the thickness swelling rate is 3.0% and the internal bonding strength is 3.0 MPa. By comparing the sawn wood board of the same tree species, the density of the reconstituted wood panel with natural wood grain is increased by 10% or more, and the thickness swelling rate is reduced by 20% or more, and the internal bonding strength has a growth of 35% or more. The panel of the present invention is manufactured by firstly peeling or slicing to obtain thick veneer(s) with splitting injury, and then impregnating with the adhesive to repair splits of veneers. The panel has advantages of good toughness, high strength, good dimensional stability, low sawline wastage, and short drying time, high production efficiency, low energy consumption and being environmentally friendly.

The board for a musical instrument according to the present disclosure includes: a first base layer; and a pair of first reinforcement layers laminated on both face sides of the first base layer, in which the first reinforcement layers includes a fiber and a binder, and the fiber is a polyparaphenylenebenzobisoxazole fiber, a liquid crystal polyester fiber, an aramid fiber, a polyarylate fiber, an ultra high-molecular weight polyethylene fiber, a polyethylene naphthalate fiber or a glass fiber.

A composite trim molding assembly includes a composite outer shell having at least one pressed or molded surface feature and a core disposed within the composite outer shell for at least one of strengthening or stiffening the outer shell. The composite trim molding assembly can be configured as a door jamb. For example, the composite outer shell can include a flat jamb, and the at least one pressed or molded surface feature can include a stop. The core can include a protrusion into a cavity formed by the stop. The cavity formed by the stop may also be hollow. The composite outer shell can be molded from a slurry and/or pressed from a flat composite panel. The at least one pressed or molded surface feature can include a surface texture (e.g., a wood grain pattern). The core can include segments fastened together, particle board, and/or fiberboard.

A method to produce a veneered element, the method including applying a first layer on a substrate, applying a second layer on a veneer layer, applying the veneer layer with the second layer applied thereto on the first layer, such that the second layer is facing the first layer, pressing the first layer, the second layer and the veneer layer together to form a veneered element, thereby material originating from the second layer permeates into the veneer layer, and wherein, after pressing, the first layer is visible through a crack, cavity, hole and/or knot of the veneer layer. Also, a veneered element.

A method to produce a veneered element, the method including applying a first layer on a substrate, applying a second layer on the first layer, applying a veneer layer on the second layer, pressing the first layer, the second layer and the veneer layer together to form a veneered element, wherein, after pressing, the second layer is transparent or translucent such that the first layer is visible through a crack, cavity, hole and/or knot of the veneer layer. Also, such a veneered element.

A method to at least partially coat a building panel, including applying a first coating composition on a building panel having a surface including at least portions including amino resins, for forming a first coating on at least said portions of said surface, wherein the first coating composition has a glass transition temperature less than 30 C. and reactive portions, applying a second coating composition on at least portions of the first coating for forming a second coating, wherein the second coating composition includes reactive portions adapted to react with the reactive portions of the first coating. The disclosure also relates to such a coated building panel.

A method of and system for producing Class-A fire-protected truss structures constructed from: a plurality of lumber pieces dip-coated with clean fire inhibiting chemical (CFIC) liquid to form a plurality of Class-A fire-protected lumber pieces; and a set of heat-resistant chemical-coated metal truss connector plates for connecting together the plurality of Class-A fire-protected lumber pieces to form a Class-A fire-protected truss structure. The improved Class-A fire-protected truss structures can be used in constructing safer roofing and/or flooring systems in wood-framed buildings, having improved fire performance characteristics.

An automated lumber fabrication factory supporting an automated process for continuously fabricating cross-laminated timber (CLT) products that are automatically dip-coated in a reservoir of clean fire inhibiting chemical (CFIC) liquid, so as to produce Class-A fire-protected CLT products in a highly automated matter.