Abstract: A laminate includes multiple paper layers, with at least one induction coil comprising first and second sets of windings. Two or more paper layers include the sets of windings comprising an electrically-conductive material. The sets of windings may be distributed throughout the laminate layers and provide good wireless induction charging performance in a compact space.

Abstract: A laminate includes multiple paper layers, with at least one induction coil comprising first and second sets of windings. Two or more paper layers include the sets of windings comprising an electrically-conductive material. The sets of windings may be distributed throughout the laminate layers and provide good wireless induction charging performance in a compact space.

Abstract: A laminate having an integrated electrical component disposed within the laminate is disclosed. The laminate includes a first paper layer having at least first and second vias through the first paper layer; a first electrically-conductive layer, comprising an electrically-conductive material, disposed over a portion of the first paper layer; a second electrically-conductive layer, comprising the electrically-conductive material, disposed over another portion of the first paper layer; an electrical component disposed over the first and second electrically-conductive layers; and an insulating layer disposed over the electrical component. The first paper layer and the insulating layer encapsulate the first electrically-conductive layer, the second electrically-conductive layer, and the electrical component.

Abstract: Decorative surfacing materials which comprise: a compressed, cured plurality of stacked laminate core layer members coated or impregnated with a resin, and an indicator mark comprising a pre-bonded composite label, wherein one of the plurality of laminate core layer members is a surface layer having an exterior-facing outer surface and the indicator mark is embedded within the exterior-facing outer surface, and wherein the exterior-facing outer surface comprises a continuous and substantially uniform outermost layer of resin are described along with processes for preparing the same.

Abstract: Electrically-conductive ink compositions comprising: (i) a particulate, electrically-conductive material; (ii) a carrier liquid; (iii) a polymer binder; and (iv) a microcrystalline cellulose component; methods comprising: (a) providing a substrate; (b) providing an electrically-conductive ink formulation comprising (i) a particulate, electrically-conductive material; (ii) a carrier liquid; (iii) a polymer binder; and (iv) a microcrystalline cellulose component; and (c) forming an electrically-conductive trace on a surface of the substrate; and articles comprising a substrate having a surface and an electrically-conductive trace formed on the surface of the substrate, wherein the electrically-conductive trace comprises: (a) a particulate, electrically-conductive material; (b) a polymer binder; and (c) a microcrystalline cellulose component are described.

Abstract: A laminate having an integrated electrical component disposed within the laminate is disclosed. The laminate includes a first paper layer having at least first and second vias through the first paper layer; a first electrically-conductive layer, comprising an electrically-conductive material, disposed over a portion of the first paper layer; a second electrically-conductive layer, comprising the electrically-conductive material, disposed over another portion of the first paper layer; an electrical component disposed over the first and second electrically-conductive layers; and an insulating layer disposed over the electrical component. The first paper layer and the insulating layer encapsulate the first electrically-conductive layer, the second electrically-conductive layer, and the electrical component.

Abstract: A laminate having an integrated electrical component disposed within the laminate is disclosed. The laminate includes a first paper layer having at least first and second vias through the first paper layer; a first electrically-conductive layer, comprising an electrically-conductive material, disposed over a portion of the first paper layer; a second electrically-conductive layer, comprising the electrically-conductive material, disposed over another portion of the first paper layer; an electrical component disposed over the first and second electrically-conductive layers; and an insulating layer disposed over the electrical component. The first paper layer and the insulating layer encapsulate the first electrically-conductive layer, the second electrically-conductive layer, and the electrical component.

Abstract: A laminate with a photovoltaic cell (e.g., an organic photovoltaic cell, or an inorganic photovoltaic cell) embedded within the laminate includes a first paper layer; a first electrically-conductive layer comprising an electrically-conductive material, the first electrically-conductive layer being disposed over the first paper layer; at least one photovoltaic active material layer disposed over the first electrically-conductive layer; a second electrically-conductive layer comprising a translucent electrically-conductive material, the second electrically-conductive layer being disposed over the photovoltaic active material layer; a translucent insulating layer disposed over the second electrically-conductive layer, wherein the first paper layer and the translucent insulating layer encapsulate the photovoltaic cell comprising the first electrically-conductive layer, the photovoltaic active material layer, and the second electrically-conductive layer within the laminate.

Abstract: Electrically-conductive ink compositions comprising: (i) a particulate, electrically-conductive material; (ii) a carrier liquid; (iii) a polymer binder; and (iv) a microcrystalline cellulose component; methods comprising: (a) providing a substrate; (b) providing an electrically-conductive ink formulation comprising (i) a particulate, electrically-conductive material; (ii) a carrier liquid; (iii) a polymer binder; and (iv) a microcrystalline cellulose component; and (c) forming an electrically-conductive trace on a surface of the substrate; and articles comprising a substrate having a surface and an electrically-conductive trace formed on the surface of the substrate, wherein the electrically-conductive trace comprises: (a) a particulate, electrically-conductive material; (b) a polymer binder; and (c) a microcrystalline cellulose component are described.

Abstract: A laminate includes multiple paper layers, with at least one induction coil comprising first and second sets of windings. Two or more paper layers include the sets of windings comprising an electrically-conductive material. The sets of windings may be distributed throughout the laminate layers and provide good wireless induction charging performance in a compact space.

Abstract: A laminate having an integrated electrical component disposed within the laminate is disclosed. The laminate includes a first paper layer having at least first and second vias through the first paper layer; a first electrically-conductive layer, comprising an electrically-conductive material, disposed over a portion of the first paper layer; a second electrically-conductive layer, comprising the electrically-conductive material, disposed over another portion of the first paper layer; an electrical component disposed over the first and second electrically-conductive layers; and an insulating layer disposed over the electrical component. The first paper layer and the insulating layer encapsulate the first electrically-conductive layer, the second electrically-conductive layer, and the electrical component.

Abstract: A laminate includes multiple paper layers, with at least one induction coil comprising first and second sets of windings. Two or more paper layers include the sets of windings comprising an electrically-conductive material. The sets of windings may be distributed throughout the laminate layers and provide good wireless induction charging performance in a compact space.

Abstract: Decorative, multi-layer surfacing materials, surfaces made therewith, methods of making such and wireless power transmission using the same, which surfacing materials comprise: a first resin-impregnated paper layer and a second resin-impregnated paper layer, and a first conductive material having a first terminus and a second terminus and capable of carrying an electric current from the first terminus to the second terminus; wherein the first conductive material is disposed on a first surface of the first resin-impregnated paper layer; wherein the first resin-impregnated paper layer and the second resin-impregnated paper layer are disposed in a stacked and compressed such that the first conductive material is encapsulated between the first resin-impregnated paper layer and the second resin-impregnated paper layer; and wherein at least one of the first resin-impregnated paper layer, the second resin-impregnated paper layer or an optional additional resin-impregnated paper layer is a decorative layer,

Abstract: Decorative, multi-layer surfacing materials, surfaces made therewith, methods of making such and wireless power transmission using the same, which surfacing materials comprise: a first resin-impregnated paper layer and a second resin-impregnated paper layer, and a first conductive material having a first terminus and a second terminus and capable of carrying an electric current from the first terminus to the second terminus; wherein the first conductive material is disposed on a first surface of the first resin-impregnated paper layer; wherein the first resin-impregnated paper layer and the second resin-impregnated paper layer are disposed in a stacked and compressed such that the first conductive material is encapsulated between the first resin-impregnated paper layer and the second resin-impregnated paper layer; and wherein at least one of the first resin-impregnated paper layer, the second resin-impregnated paper layer or an optional additional resin-impregnated paper layer is a decorative layer.

Abstract: Decorative, multi-layer surfacing materials, surfaces made therewith, methods of making such and wireless power transmission using the same, which surfacing materials comprise: a first resin-impregnated paper layer and a second resin-impregnated paper layer, and a first conductive material having a first terminus and a second terminus and capable of carrying an electric current from the first terminus to the second terminus; wherein the first conductive material is disposed on a first surface of the first resin-impregnated paper layer; wherein the first resin-impregnated paper layer and the second resin-impregnated paper layer are disposed in a stacked and compressed such that the first conductive material is encapsulated between the first resin-impregnated paper layer and the second resin-impregnated paper layer; and wherein at least one of the first resin-impregnated paper layer, the second resin-impregnated paper layer or an optional additional resin-impregnated paper layer is a decorative layer.

Abstract: Embodiments of the present invention are directed to substantially formaldehyde-free laminates and methods of making substantially formaldehyde-free laminates, wherein the method comprises providing at least one layer of decorative paper; applying at least one polymer coating that is substantially formaldehyde free onto at least one surface of the decorative paper; electron beam curing the at least one polymer coating onto the decorative paper; providing one or more layers of core paper onto the coated decorative paper, wherein the core paper is impregnated with a resin that is substantially formaldehyde free; and hot pressing the core paper and coated decorative paper to form the substantially formaldehyde-free laminate.

Abstract: A decorative laminate is provided and includes a core with at least one epoxy resin impregnated fiberboard sheet. The decorative laminate also includes at least one decorative layer provided adjacent to the core. A method of forming a decorative laminate is also provided.

Abstract: A decorative laminate having improved scratch and abrasion resistance is provided. In one embodiment, the decorate laminate includes a substrate or core, a decorative sheet on the substrate, and an overlay sheet on the decorative sheet. The overlay sheet is coated on both major surfaces to provide scratch and abrasion resistance to the laminate. The coating on the interior facing surface contains mineral particles having a particle size of from between about 10-30 microns. The coating on the exterior facing surface contains a mixture of first mineral particles having a particle size of from between about 3-8 microns and second mineral particles having a particle size of less than about 1.0 micron. The first mineral particles are preferably alumina particles, and the second mineral particles are preferably sol gel process alumina particles.

Abstract: A decorative laminate is provided and includes a core having a plurality of stacked paper sheets which are impregnated therein a melamine-formaldehyde resin and an internal plasticizer for the melamine-formaldehyde resin, the plasticizer comprising an amino-functional monomer; a decorative sheet overlying the core, the decorative sheet having impregnated therein a melamine-formaldehyde resin and an internal plasticizer for the melamine-formaldehyde resin; and, optionally, an overlay sheet on the decorative sheet. A combustion accelerant is also included in the resin.

Abstract: A wood veneer surfaced laminate and method of making it are provided which produces a product having the appearance of a natural wood product, but with the toughness, moisture resistance, stain resistance, impact resistance, and abrasion resistance of melamine resin surfaced laminate products. The wood veneer surfaced laminate is made by providing a sheet of a natural or engineered wood veneer; impregnating the sheet with a first liquid curable resin such that said liquid resin substantially completely impregnates the sheet; coating a second liquid curable resin onto a surface of the sheet; laminating the sheet to a core while curing the resins to form a natural or engineered wood veneer surfaced laminate.