An architectural structure having: a wall of a room of the architectural structure; and a panel integrated into the wall, wherein the panel includes thermoelectric components (TECs) arranged as a TEC grid, thereby defining a radiant panel, wherein: the TECs, of the TEC grid, are thermally coupled to a common heat sink formed in part by an exterior surface of the wall; and the wall defines a wall surface area, the panel defines a panel surface area, and the panel surface area is between 5% and 20% of the wall surface area.

A material and method for insulating a top portion of a foundation wall which includes a non-woven thermoplastic board for insulating a foundation wall. The non-woven thermoplastic board has a thermal resistance of an R-value per inch thickness of at least 1.

A conductive concrete electric thermal battery includes conductive concrete; and a plurality of electrodes disposed in the conductive concrete, each electrode of the plurality of electrodes is mechanically isolated from every other electrode of the plurality of electrodes and configured to connect electrically to a source of electrical energy. The conductive concrete includes a mixture of concrete and at least one conductive material.

A conductive concrete electric thermal battery includes conductive concrete; and a plurality of electrodes disposed in the conductive concrete, each electrode of the plurality of electrodes is mechanically isolated from every other electrode of the plurality of electrodes and configured to connect electrically to a source of electrical energy. The conductive concrete includes a mixture of concrete and at least one conductive material.

The present invention is directed to a wall assembly comprising a novel structural lattice frame comprising vertical studs and outwardly located horizontal furring spaced with thermal isolation pads therebetween at the framing intersections, foam insulation encapsulating the furring and at least a portion of the vertical studs, and an exterior air- and water-resistant barrier-protected sheathing fastened to the outward side of the horizontal furring.

The present invention is directed to a wall assembly comprising a novel structural lattice frame comprising vertical studs and outwardly located horizontal furring spaced with thermal isolation pads therebetween at the framing intersections, foam insulation encapsulating the furring and at least a portion of the vertical studs, and an exterior air- and water-resistant barrier-protected sheathing fastened to the outward side of the horizontal furring.

A desiccant window includes: a transparent triangular prism that is disposed between first and second plates, is configured of a first side along the first glass and second and third sides which have an angle with respect to the first side in a sectional view, and forms (three) types of optical paths; and a desiccant heat receiving unit that has hygroscopicity and is disposed between the first and second plates, is installed on the second side of the triangular prism), and is received solar heat and releases absorbed moisture by heating using the received heat received.

A desiccant window includes: a transparent triangular prism that is disposed between first and second plates, is configured of a first side along the first glass and second and third sides which have an angle with respect to the first side in a sectional view, and forms (three) types of optical paths; and a desiccant heat receiving unit that has hygroscopicity and is disposed between the first and second plates, is installed on the second side of the triangular prism), and is received solar heat and releases absorbed moisture by heating using the received heat received.

A thermal isolator system may comprise a thermal isolator configured to be coupled to an inner wall of a wall system, and a first retainer comprising a first coupling protrusion having a first protrusion shape. The thermal isolator may comprise an isolator body spanning between an isolator outer surface and an isolator inner surface and between an isolator first side and an isolator second side, and a first coupling recess disposed through the isolator outer surface and into the isolator body. The first coupling recess may comprise a recess shape, and the first protrusion shape of the first coupling protrusion may be complementary to the recess shape of the first coupling recess. The first retainer may be configured to be coupled to the thermal isolator by the first coupling protrusion being disposed in the first coupling recess of the thermal isolator.

A wall structure and a method for forming a wall structure is provided using three-dimensional printing of extruded building material applied to a surface of a building structure. According to one embodiment, the wall structure includes a pair of outer wythes spaced from an inner wythe. The outer wythes can include a core extending between the pair of outer wythes and toward the inner wythe. A protrusion can also extend toward the inner wythe a spaced distance from the inner wythe or entirely toward and adjoining the inner wythe. The core is configured with an inwardly facing spaced opposed surfaces of the outer wythes surrounding a vertically extending rebar, with grout surrounding that rebar. Horizontally extending support pins can be spaced parallel from each other and extend from the protrusions and into the inner wythe.