A one-piece component comprising a tetrahedral-octahedral honeycomb lattice is disclosed herein, along with a mold, a system and methods of making the component. A one-piece component comprising a truncated tetrahedral-octahedral honeycomb lattice also is disclosed, along with corresponding molds, systems and methods.

A latent heat storage window includes a plurality of cells, an operation mechanism, and a magnetic material. The plurality of cells are formed by encapsulating a latent heat storage material including two or more components. The operation mechanism can be operated by a user. The magnetic material causes a specific component of the two or more components included in the latent heat storage material to be unevenly distributed when the operation mechanism is operated.

A latent heat storage window includes a plurality of cells, an operation mechanism, and a magnetic material. The plurality of cells are formed by encapsulating a latent heat storage material including two or more components. The operation mechanism can be operated by a user. The magnetic material causes a specific component of the two or more components included in the latent heat storage material to be unevenly distributed when the operation mechanism is operated.

The present invention proposes a novel construction system consisting of the attachment of modified hyperboloid shaped-structural elements called “laminate cells” which, when working together, create a structural system with integrated over having the capacity of absorbing and transmitting in all directions and orientations.

The present invention proposes a novel construction system consisting of the attachment of modified hyperboloid shaped-structural elements called “laminate cells” which, when working together, create a structural system with integrated over having the capacity of absorbing and transmitting in all directions and orientations.

A system and a method for securing a first composite panel to a second composite panel include a latch assembly having one or more latches. The latch assembly is configured to be secured to one of the first composite panel or the second composite panel. One or more strikes are configured to retain at least a portion of the one or more latches. The one or more strikes are configured to be secured to the other of the first composite panel or the second composite panel.

A residential or commercial building, structure, or building component can include an exterior member, interior member, and plurality of cross-members spatially disposed therebetween. Each of the exterior member, interior member, cross-members can be formed from a multi-layered stack of polymeric material made by a layered three-dimensional printing process, and all can be monolithically integrated. An exterior surface region of the exterior member can have an integrally formed surface finish. Overlying finishing or connective layers can be added. The exterior and interior members can be configured in a parallel arrangement to form a rectangular or curve shaped building block. A fill material can be disposed into openings between the exterior and interior members, and an interior surface region at the interior member can include a cavity configured for an electrical box, plumbing, or a sensing device.

A bridging element is positioned between a pair of insulating outer layers and a pair of rigid supporting inner layers. The bridging element includes a plurality of spaced-apart ribs supporting the rigid inner layers in a spaced-apart overlying relationship with a flexible sealing layer surrounding the plurality of spaced-apart ribs to form a first sleeve and another flexible sealing layer surrounding the supporting inner layers to form a second sleeve. The pair of insulating outer layers includes a composite assembly formed from non-metallic fibers and a thermal insulating material matrix.

Systems and methods are described herein for a panelized building assembly. In one example, an assembly may include one or more of a first composite planar panel, and second composite planar panel, and a planar joining element. The first and second planar panels may include a core material sandwiched between two fiber-reinforced skin elements. Each of the panels may include a first block of fiber-reinforced material coupled to at least one of the skin elements, which may define two slots for receiving the planar joining element. In some cases, the planar joining element, when placed within the slots of two panels to be joined, may transfer a load between the fiber-reinforced material of the two panels. The resulting joint may form a water-tight and fire-retardant seal.

Systems and methods are described herein for a panelized building assembly comprising a double skeleton of planar connectors, positioned parallel to and behind the inner and outer building surfaces of panels to be connected. The planar elements may be folded symmetrically about the bisected angle between adjacent surfaces so as to form a coherent and continuous double layer that can, in some cases, offers structural, fire, acoustical and waterproofing performance consistently between various panel. The connectors may extend into the mass of a block of material that forms a continuous edge around the perimeter of the panels, which is bonded continuously to the fiber-reinforced skin of the panel and to the core material that the inner and outer fiber reinforced skins are also continuously bonded to.