A power module is configured to accept power from a cable, wherein the power module may be inserted into a standard wall cavity via a small hole. A processor module coupled to the power module comprises a processor and is configured to accept power from the cable for the processor, wherein the processor module may be inserted into the standard wall cavity via the small hole. A sensor module coupled to the processor module, comprises a sensor and is configured to accept input from the sensor for the processor, wherein the sensor module may be inserted into the small hole.

A wireless electrical power transmission system includes a panel having a recessed area for receiving a wireless power transmitter, such as an electric field resonant transmitter. The panel has a first outer surface and a second outer surface opposite the first outer surface, with a thickness defined between the first and second outer surfaces. The recessed area is formed in the first outer surface, and the recessed area has a depth that is less than the thickness of the panel. Electrical wiring is coupled to the wireless power transmitter and passes through an opening formed in the panel, which opening is accessible from the recessed area, and the electrical wiring is in communication with an electrical power source.

An improved mounting block has a base plate portion and a face plate portion. Base plate portion has an outer surface extending outward from a mounting surface and is selectively attachable to the face plate portion. One of the face plate portion and the base plate portion has a plurality of snap fit teeth formed thereon, and the other has a plurality of snap fit receivers, configured to selectively receive the snap fit teeth. Face plate portion may include flange flex grooves formed in an attachment flange, allowing walls to deflect independently from corners, such that the flange flex grooves allow the attachment flange to flex outward from the outer surface. Base plate portion may include alignment ribs extending outward from the outer surface, such that the flange flex grooves formed in the attachment flange interface with the alignment ribs formed on the base plate portion.

An improved mounting block has a base plate portion and a face plate portion. Base plate portion has an outer surface extending outward from a mounting surface and is selectively attachable to the face plate portion. One of the face plate portion and the base plate portion has a plurality of snap fit teeth formed thereon, and the other has a plurality of snap fit receivers, configured to selectively receive the snap fit teeth. Face plate portion may include flange flex grooves formed in an attachment flange, allowing walls to deflect independently from corners, such that the flange flex grooves allow the attachment flange to flex outward from the outer surface. Base plate portion may include alignment ribs extending outward from the outer surface, such that the flange flex grooves formed in the attachment flange interface with the alignment ribs formed on the base plate portion.

A multilayer structure for the production of a heating floor or wall covering or similar includes a decorative layer made up of at least one plastic surface layer. The decorative layer is bonded onto a heating layer, which heating layer is bonded onto a sublayer intended to be installed on the floor or a wall or the like. The heating layer is made up of a conductive band comprising conductive particles homogeneously distributed over the surface and/or in the thickness of said conductive band, which supports at least three conductive electrodes spaced from one another so as to define a discontinuous heating surface.

A multilayer structure for the production of a heating floor or wall covering or similar includes a decorative layer made up of at least one plastic surface layer. The decorative layer is bonded onto a heating layer, which heating layer is bonded onto a sublayer intended to be installed on the floor or a wall or the like. The heating layer is made up of a conductive band comprising conductive particles homogeneously distributed over the surface and/or in the thickness of said conductive band, which supports at least three conductive electrodes spaced from one another so as to define a discontinuous heating surface.

The present invention is generally directed to energy storage systems comprising manufactured architectural materials having electrical battery systems embedded therein. The manufactured materials are generally provided as architectural panels, such as panels useful for interior or exterior cladding for buildings, flooring, countertops, or stairs. The panels comprise at least one battery device or battery assembly that is over-formed by and/or bonded with the architectural material. In preferred embodiments, the panels are formed by flowing a viscous architectural material precursor around the battery device or assembly and curing the precursor so as to solidify the architectural material. The panels may be electrically connected in any number of various arrangements, which can be chosen based on the specific application for the energy storage system.

The present invention is generally directed to energy storage systems comprising manufactured architectural materials having electrical battery systems embedded therein. The manufactured materials are generally provided as architectural panels, such as panels useful for interior or exterior cladding for buildings, flooring, countertops, or stairs. The panels comprise at least one battery device or battery assembly that is over-formed by and/or bonded with the architectural material. In preferred embodiments, the panels are formed by flowing a viscous architectural material precursor around the battery device or assembly and curing the precursor so as to solidify the architectural material. The panels may be electrically connected in any number of various arrangements, which can be chosen based on the specific application for the energy storage system.

A composite wall, ceiling or floor panel (10), system and method, including a sheet (14) having a first face (18) including at least one first mounting portion (16), and at least one formwork member (20) with at least one second mounting portion (30) arranged to engage with the first mounting portion of the sheet to retain the sheet and said at least one formwork member together. Structural support comes from piers (for a wall) or beams (ceiling or floor) formed in the spacing between adjacent formwork members. The formwork members act as the core of a wall, ceiling or floor panel. An external coating (123) is applied to the formwork members, such as spray shotcrete or render. Channels (28) formed by the formwork members defines integrated ducting for services to be run.

A building envelope for a building wall, floor, or roof of a building, includes at least two shells spaced some distance apart from one another, which encloses an intermediate space therebetween, the shells including an exterior-facing shell configured to face an exterior of the building, and an interior-facing shell configured to face an interior of the building. The shells spaced apart from one another are filled with a building material and optionally include structural reinforcement and supply-engineering elements.