A building system and method of using the same may include a wall assembly including a plurality of expanded metal mesh sheets disposed on either side of at least one welded wire mesh sheet. The wall assembly may be disposed in a keyway defined by a foundation assembly including a plurality of form boards. The foundation assembly may be constructed and arranged for framing out a slab, wall, or structure. The building system may further include a framing assembly including a plurality of vertical supports spaced away from one another and being constructed and arranged to connect to a support header and plurality of spans such that a structure or wall may be formed within the framing assembly. Material, such as concrete, maybe poured between the plurality of expanded metal mesh sheets to form a slab, wall, or structure.

A concrete wall frame assembly and a method of manufacturing same is disclosed. The assembly includes two generally parallel metal plates and at least one rod extending between a first end and a second end. A first end of the rod is passed through a hole in the second plate toward the first plate until the first end engages a continuous inner surface of the first plate. The second end of the rod protrudes through the hole and extends past an outer surface of the second plate. A stud welder is connected to the either the second, protruding end of the rod, or connected to the rod between the two metal plates to stud weld the first rod end to the inner surface of the first plate. The second end of the rod is then arc welded to the second metal plate at the outer surface.

A concrete wall frame assembly and a method of manufacturing same is disclosed. The assembly includes two generally parallel metal plates and at least one rod extending between a first end and a second end. A first end of the rod is passed through a hole in the second plate toward the first plate until the first end engages a continuous inner surface of the first plate. The second end of the rod protrudes through the hole and extends past an outer surface of the second plate. A stud welder is connected to the either the second, protruding end of the rod, or connected to the rod between the two metal plates to stud weld the first rod end to the inner surface of the first plate. The second end of the rod is then arc welded to the second metal plate at the outer surface.

Systems and methods for forming insulated sandwich walls are provided. Outer and inner support members are located between inner and outer strongbacks. Structural material for an outer wall, such as concrete, is deposited between the outer strongback and outer support member. Structural material for an inner wall is deposited between the inner strongback and inner support member. An insulating material is deposited between the outer and inner support members to form an insulating core.

The object of the invention relates to a neutron absorbing concrete wall (10), which concrete wall (10) has an internal delimiting surface (11a), and an external delimiting surface (11b) on an opposite side to the internal delimiting surface (11a), the essence of which is that it contains a first concrete layer (13a) on the side of the internal delimiting surface (11a), and a second concrete layer (13b) on the side of the external delimiting surface (11b), which first concrete layer (13a) contains at least 0.05 mass % boron-10 isotope (10B), and the second concrete layer (13b) is formed as heavyweight concrete. The object of the invention also relates to a method for creating a neutron radiation absorbing concrete wall (10) that has an internal delimiting surface (11a), and an external delimiting surface (11b) on an opposite side to the internal delimiting surface (11a), the essence of which is a first concrete layer (13a) containing at least 0.05 mass % boron-10 isotope (.sup.10B) is formed on the side of the internal delimiting surface (11a), and a second concrete layer (13b) created as heavyweight concrete is formed on the side of the external delimiting surface (11b). The object of the invention also relates to a neutron absorbing concrete wall (10), the essence of which is that it is formed as heavyweight concrete containing at least 0.05 mass % boron-10 isotope (.sup.10B).

The object of the invention relates to a neutron absorbing concrete wall (10), which concrete wall (10) has an internal delimiting surface (11a), and an external delimiting surface (11b) on an opposite side to the internal delimiting surface (11a), the essence of which is that it contains a first concrete layer (13a) on the side of the internal delimiting surface (11a), and a second concrete layer (13b) on the side of the external delimiting surface (11b), which first concrete layer (13a) contains at least 0.05 mass % boron-10 isotope (10B), and the second concrete layer (13b) is formed as heavyweight concrete. The object of the invention also relates to a method for creating a neutron radiation absorbing concrete wall (10) that has an internal delimiting surface (11a), and an external delimiting surface (11b) on an opposite side to the internal delimiting surface (11a), the essence of which is a first concrete layer (13a) containing at least 0.05 mass % boron-10 isotope (.sup.10B) is formed on the side of the internal delimiting surface (11a), and a second concrete layer (13b) created as heavyweight concrete is formed on the side of the external delimiting surface (11b). The object of the invention also relates to a neutron absorbing concrete wall (10), the essence of which is that it is formed as heavyweight concrete containing at least 0.05 mass % boron-10 isotope (.sup.10B).

The present invention provides a bidirectional energy-transfer system comprising: a thermally and/or electrically conductive concrete, disposed in a structural object; a location of energy supply or demand that is physically isolated from, but in thermodynamic and/or electromagnetic communication with, the thermally and/or electrically conductive concrete; and a means of transferring energy between the structural object and the location of energy supply or demand. The system can be a single node in a neural network. The thermally and/or electrically conductive concrete includes a conductive, shock-absorbing material, such as graphite. Preferred compositions are disclosed for the thermally and/or electrically conductive concrete. The bidirectional energy-transfer system may be present in a solar-energy collection system, a grade beam, an indoor radiant flooring system, a structural wall or ceiling, a bridge, a roadway, a driveway, a parking lot, a commercial aviation runway, a military runway, a grain silo, or pavers, for example.

Improved tilt-up and precast construction panels and improved methods for creating the same address deficiencies in the current tilt-up and precast construction panels. Improved tilt-up and precast construction panels use less concrete and less steel reinforcement and weigh less than current tilt-up and precast construction panels. Additionally, improved tilt-up and precast construction panels have greater insulative properties (both heat and sound) than do current tilt-up and precast construction panels. Improved tilt-up and precast construction panels require less labor on the construction site, thereby increasing efficiency and profitability of construction crews. Additional advantages of implementations of the invention will become apparent through the following description and by practice of implementations of the invention.

Improved tilt-up and precast construction panels and improved methods for creating the same address deficiencies in the current tilt-up and precast construction panels. Improved tilt-up and precast construction panels use less concrete and less steel reinforcement and weigh less than current tilt-up and precast construction panels. Additionally, improved tilt-up and precast construction panels have greater insulative properties (both heat and sound) than do current tilt-up and precast construction panels. Improved tilt-up and precast construction panels require less labor on the construction site, thereby increasing efficiency and profitability of construction crews. Additional advantages of implementations of the invention will become apparent through the following description and by practice of implementations of the invention.

A panelized lath and drainage plane panel and system is disclosed. A panel comprises a patterned polymer board providing a continuous drainage plane and a metallic lath affixed to the patterned polymer board, such that a first pair of adjacent edges include an exposed surface of the patterned polymer board. The panel may also include a second pair of adjacent edges, opposite the first pair of adjacent edges include an overhang of metallic lath. The system provides an open-air space between the exterior of the structure and the polymer board to allow the egress of liquid water and water vapor. A wall system using such panels is also disclosed. Typically, a manmade or natural stone veneer or a stucco is applied over the system.