Abstract: A multi-layer laminate may include a substrate, a printed build layer adjacent the substrate and defining a texture having elevated areas and areas of relief, a printed image layer adjacent the build layer, and a coating layer having a mineral loading and a method for creating a textured laminate may include steps to cause the printed image to be in registration with the texture.

Abstract: Disclosed are boot (and other footwear) dryer insert materials that are to be used to dry out boots without the use of electric or mechanical power. Said boot insert dryer materials utilize a low bioburden, biodegradable and/or compostable moisture absorbing nonwoven structure and one or more antimicrobial and/or antifungal agents that minimize odor by mitigating the spread of odor causing pathogens. The drying process includes the ability of the outer surface of the boot dryer to allow the ingress of moisture absorbed from the boot while at the same time preventing captured moisture to escape back into the boot. Fluid absorbing or superabsorbent, capabilities may be incorporated in the devices of the present invention to control excess fluids. Also disclosed are methods of manufacture of the boot dryer inserts of the present invention.

Abstract: Biolaminate composite assemblies are provided. Generally, the biolaminate composite assemblies may comprise one or more biolaminate layers and at least one biolaminate layer may comprise polylactic acid. In one embodiment, a biolaminate composite assembly is provided comprising one or more biolaminate layers wherein the biolaminate composite assembly is three-dimensionally formable over a rigid non-plastic substrate. At least one of the biolaminate layers comprises polylactic acid and a natural wax. In another embodiment, a method for forming a biolaminate composite assembly is provided.

Abstract: Biolaminate composite assemblies are provided. Generally, the biolaminate composite assemblies may comprise one or more biolaminate layers and at least one biolaminate layer may comprise polylactic acid. In one embodiment, a biolaminate composite assembly is provided comprising one or more biolaminate layers wherein the biolaminate composite assembly is three-dimensionally formable over a rigid non-plastic substrate. At least one of the biolaminate layers comprises polylactic acid and a natural wax. In another embodiment, a method for forming a biolaminate composite assembly is provided.

Abstract: Cellulosic biolaminate assemblies are provided. In one embodiment, a biolaminate structure is provided comprising a first cellulosic layer, a second cellulosic layer, and a first bio-based polymer. The first bio-based polymer impregnates the first cellulosic layer and the second cellulosic layer. The first cellulosic layer and the second cellulosic layer are fused together.

Abstract: Cellulosic biolaminate assemblies are provided. In one embodiment, a biolaminate structure is provided comprising a first cellulosic layer, a second cellulosic layer, and a first bio-based polymer. The first bio-based polymer impregnates the first cellulosic layer and the second cellulosic layer. The first cellulosic layer and the second cellulosic layer are fused together.

Abstract: Biolaminate assemblies for use as high pressure laminates are provided. In one embodiment, the biolaminate assembly includes a surface wear layer including polylactic acid and at least one of a plastic and mineral. The surface wear layer is adapted to be laminated or thermoformed to a nonplastic rigid substrate. The surface wear layer has a wear resistant range greater than about 400 cycles using tabor abrasion and temperature resistance range from about 212° F. to about 356° F. such that the biolaminate assembly is suitable for use as a high pressure laminate.

Abstract: Cellulosic biolaminate assemblies are provided. In one embodiment, a biolaminate structure is provided comprising a first cellulosic layer, a second cellulosic layer, and a first bio-based polymer. The first bio-based polymer impregnates the first cellulosic layer and the second cellulosic layer. The first cellulosic layer and the second cellulosic layer are fused together.

Abstract: Embodiments of the invention relate to a biolaminate composite assembly, including one or more biolaminate layers, a non-plastic rigid substrate and an adhesive layer in contact with the substrate and the one or more biolaminate layers. The one or more biolaminate layers is laminated or formed to the substrate.