Described herein is a wall assembly for use in walls of energy efficient residential or commercial buildings which can provide improved thermal resistance, moisture resistance and structural capacity. The wall assembly includes a frame assembly; a laminated outer sheathing layer; and a closed cell inner foam layer for coupling the layer to the frame assembly. Also described herein is a method of manufacturing the wall assembly.

A moveable wall system and components therefore, including: 1. A flexible power connector configured to flex in only one direction whereby it can be pushed without buckling; 2. at least one wireless power transmission receiving station in one or more of the moveable wall and modular units mounted thereon, for receiving the wireless transmission of power and enable one to charge electronic devices and provide power to power receiving lamps or the like, without the need for plug-in electrical wiring; 3. an overhead track system for supporting the moveable wall laterally below at least two spaced parallel tracks, the wall including a core support member having at least two spaced frame members secured to the top of said core support and projecting laterally to either or both sides of core support, each including a pair of trolleys for suspending said moveable wall in said parallel overhead tracks, projecting upwardly from its respective frame member and engaging their respective track.

A moveable wall system and components therefore, including: 1. A flexible power connector configured to flex in only one direction whereby it can be pushed without buckling; 2. at least one wireless power transmission receiving station in one or more of the moveable wall and modular units mounted thereon, for receiving the wireless transmission of power and enable one to charge electronic devices and provide power to power receiving lamps or the like, without the need for plug-in electrical wiring; 3. an overhead track system for supporting the moveable wall laterally below at least two spaced parallel tracks, the wall including a core support member having at least two spaced frame members secured to the top of said core support and projecting laterally to either or both sides of core support, each including a pair of trolleys for suspending said moveable wall in said parallel overhead tracks, projecting upwardly from its respective frame member and engaging their respective track.

A method of manufacturing building panels includes assembling a frame of a building panel. The frame defines at least one cavity and at least one injection aperture in fluid communication with the at least one cavity. The method also includes positioning the frame on one of a base and a shelf of a multi-panel consolidation device having a plurality of shelves, with the shelves being in an expanded configuration, and at least substantially enclosing the at least one cavity. The method also includes forcing the shelves of the multi-panel consolidation device into a collapsed configuration, and injecting an expandable polymer through the at least one injection aperture into the at least one cavity. The method further includes forcing the shelves into an expanded configuration after a predetermined period of time selected to permit the expandable polymer to form a foam bonded to the frame.

A vacuum insulated panel (VIP) and a method of manufacturing a VIP includes a rigid core material having high insulation and low conductivity properties. The rigid core may be made of an inorganic material that effectively mimics a porous silica core material. The core material includes large particles of an inorganic material having a diameter in a range of 10 μm to 50 μm. A portion of these large particles may be ground into small particles having a diameter of less than 1 μm. The small particles are mixed with a portion of the large particles to form a core material which is then mixed with a fiber skeleton and compacted under vacuum along with a fibrous skeleton for structure. The resulting structure provides a porosity ranging from 10 nm to 1 μm in diameter.

A pipe-liner system for use when lining a pipe interior features a pipe having a pipe opening end and a pipe interior wall. The system features a flexible, substantially-impermeable, elongate extender-tube and an evertable, flexible, elongate, tubular pipe-liner. The system features a substantially leak-proof pressure retaining closure-sleeve located on a pipe-liner second end. An extender-tube second end is attached to a pipe-liner first end via a substantially leak-proof connection there between. The combined extender-tube and the pipe-liner form a single continuous evertable tube, hereinafter referred to as an extended liner having the pressure retaining closure-sleeve enclosing an extended liner distal end. A length of the extender-tube and a length of the pipe-liner are each chosen so that the liner is caused to be accurately positioned within the pipe upon eversion.

The insulating barrier of a panel including has a first stratum and a second stratum, each having a plurality of ridges that face each other, and run athwart of each other. Clearance between at least some adjacent pairs of the ridges provide a mechanical chase that reaches across at least most of the panel. A cladding overlaying at least one side of the insulating barrier is denser than the barrier. The mechanical chase is in the form of a groove through which a utility feed can be routed when the panel is to be mounted in a building.

The invention is the interior face attaching mechanisms of a plastic injection molded flow-through grid forming grid panel that is used as a form for concrete/cementitious material. A “T” or nub catch is formed by the plastic injection mold halve sections at the outer ends of interior face extended vertical grids such that during a concrete/cementitious pour the “T” or nub catch, and attached forming panel connecter tie or webs, does not unduly block the flow of the concrete/cementitious material from flowing through the grid openings. The “T” or nub catch enables forming panel tie or web connecters to slide down vertically along the interior face of the concrete/cementitious material flow-through grid forming panel and downward attach to the “T” or nub catch.

A system and method for at least partially concealing a communications antenna without preventing the communications antenna from receiving electromagnetic signals, the system and method comprising a composite material that allows electromagnetic signals to be transmitted therethrough without significant degradation and which may function as a component of a building or structure in which a communications antenna is to be located or to which a communications antenna is to be attached.

The instant system is a panel made of several layers that is a highly decorative, fire resistant, water resistant, sound proof, R valued insulated, light weight, and energy efficient panel. Such layers include: glass fiber reinforced concrete, glass fiber reinforced concrete with alkaline resistant fibers, alkaline resistant hurricane tested scrim mesh, a solar powered radiant tubing, a fire resistant foam that contains a steel reinforcement, and an epoxy adhesive.