Binders, methods for making same, and methods for making composite lignocellulose products therefrom. The binder can include about 30 wt % to about 40 wt % of solids that include a urea-modified aldehyde-based resin; about 0.1 wt % to about 3 wt % of solids that include an isocyanate-based resin; about 0.1 wt % to about 12 wt % of an extender; and about 50 wt % to about 62 wt % of water, where all weight percent values are based on a total weight of the binder. The binder can have a sodium hydroxide equivalent weight alkalinity of about 3 wt % to about 9 wt %.

A manufactured wood panel or board with an integrated conveying laminate that conveys a fire resistant (FR) additive to specific locations within the panel or board during the manufacturing process, and the process and system for producing a panel or board with an FR conveying laminate. The laminate may be a natural or synthetic material with a closed (i.e., solid) or open (i.e., mesh-like) surface. In addition to providing resistance to fire spread and fire combustion, the laminate also may be selected from a group of materials that produce desired structural properties (i.e., minimize cracking, enhance structural integrity) both before and during a particular event, such as a fire event.

Composite cellulosic products and processes for making same. In some embodiments, the composite cellulosic product can include a plurality of cellulosic substrates and an at least partially cured binder. Prior to curing, the binder can include a mixture formed by combining magnesium oxide, water, and magnesium chloride. A weight ratio of the magnesium oxide to the magnesium chloride in the binder can be at least 2.2:1 to 8.5:1.

A two-part flame-retardant, a flame-retardant oriented strand (OSB) and method for forming a flame-retardant OSB is provided. The two-part flame-retardant composition includes an aqueous solution containing a water-soluble flame-retardant and a flame-retardant powder that is incorporated into an oriented strand board without substantially affecting the mechanical properties of the oriented strand board. The method includes applying the aqueous solution containing a water-soluble flame-retardant to an oriented strand board furnish and applying a flame-retardant powder to the wetted furnish, without requiring an additional drying step.

A two-part flame-retardant, a flame-retardant oriented strand (OSB) and method for forming a flame-retardant OSB is provided. The two-part flame-retardant composition includes an aqueous solution containing a water-soluble flame-retardant and a flame-retardant powder that is incorporated into an oriented strand board without substantially affecting the mechanical properties of the oriented strand board. The method includes applying the aqueous solution containing a water-soluble flame-retardant to an oriented strand board furnish and applying a flame-retardant powder to the wetted furnish, without requiring an additional drying step.

A plank has a first portion with at least three layers. The first layer is of a plant material, and has an inner surface that includes a nonwoven fabric or a fiberglass mesh. The second layer is of an adhesive paper material that includes a macromolecular glue where the macromolecular glue is 50-55% melamine, 35-40% plasticizer, and 3-5% formaldehyde. The third layer is one of bamboo, wood, or paper. The plank has a second portion, which may be of a plastic composite base material or a magnesium oxide composite base material. When the second portion is of a plastic composite material, the first portion is fused to the second portion by cold pressing or a polyurethane reactive adhesive. When the second material is of a magnesium oxide composite base material, the first portion is thermally pressed to the second portion by cold pressing, hot pressing or a polyurethane reactive adhesive.

A plank has a first portion with at least three layers. The first layer is of a plant material, and has an inner surface that includes a nonwoven fabric or a fiberglass mesh. The second layer is of an adhesive paper material that includes a macromolecular glue where the macromolecular glue is 50-55% melamine, 35-40% plasticizer, and 3-5% formaldehyde. The third layer is one of bamboo, wood, or paper. The plank has a second portion, which may be of a plastic composite base material or a magnesium oxide composite base material. When the second portion is of a plastic composite material, the first portion is fused to the second portion by cold pressing or a polyurethane reactive adhesive. When the second material is of a magnesium oxide composite base material, the first portion is thermally pressed to the second portion by cold pressing, hot pressing or a polyurethane reactive adhesive.

A two-part flame-retardant, a flame-retardant oriented strand (OSB) and method for forming a flame-retardant OSB is provided. The two-part flame-retardant composition includes an aqueous solution containing a water-soluble flame-retardant and a flame-retardant powder that is incorporated into an oriented strand board without substantially affecting the mechanical properties of the oriented strand board. The method includes applying the aqueous solution containing a water-soluble flame-retardant to an oriented strand board furnish and applying a flame-retardant powder to the wetted furnish, without requiring an additional drying step.

A composite includes a fiber and a dextrin, wherein at least part of the dextrin adheres to the fiber, the molecular weight distribution curve of the dextrin has a first maximum and a second maximum, the weight average molecular weight value based on a peak belonging to the first maximum is less than 6000, and the weight average molecular weight value based on a peak belonging to the second maximum is 6000 or more.

A method of extrusion additive manufacturing for veneer applications may include, but is not limited to, loading material into an extruder, generating a mixture from the material, and fabricating the veneer product. Fabricating the veneer product may include depositing a first portion of the mixture on a working surface of the extruder, actuating the working surface, and depositing an additional portion of the mixture on the working surface of the extruder proximate to the first position of the mixture deposited on the working surface. Where the first portion of the mixture and the additional portion of the mixture form a first layer of the veneer product, fabricating the veneer product may include actuating a nozzle of the extruder and depositing an additional layer of the mixture on the first layer of the veneer product. The material may include wood product and a binder.