A composite foam and concrete wall includes a foam layer having a top surface, a bottom surface, a left wall surface and a right wall surface wherein the foam layer comprises at least two foam panels that define a seam that is substantially parallel to the top surface and the bottom surface. A concrete layer is secured to a surface of the foam layer.

A composite foam and concrete wall includes a foam layer having a top surface, a bottom surface, a left wall surface and a right wall surface wherein the foam layer comprises at least two foam panels that define a seam that is substantially parallel to the top surface and the bottom surface. A concrete layer is secured to a surface of the foam layer.

A composite foam and concrete wall includes a foam layer having a top surface, a bottom surface, a left wall surface and a right wall surface wherein the foam layer comprises at least two foam panels that define a seam that is substantially parallel to the top surface and the bottom surface. A concrete layer is secured to a surface of the foam layer.

A composite foam and concrete wall includes a foam layer having a top surface, a bottom surface, a left wall surface and a right wall surface wherein the foam layer comprises at least two foam panels that define a seam that is substantially parallel to the top surface and the bottom surface. A concrete layer is secured to a surface of the foam layer.

Various implementations are directed to a single face building block and masonry wall assembly and methods. Each building block includes a single face shell, first and second webs extending from an interior surface of the face shell, and a pier that has a proximal surface disposed between distal ends of the webs and a distal surface that is opposite and spaced apart from the proximal surface of the pier. Interior surfaces of the webs, the proximal surface of the pier, and a portion of the interior surface of the face shell between the webs define a pocket. In addition, the building blocks may include a ledge that extends outwardly from the distal surface of the pier. This ledge forms a channel with an upper surface of the pier stacked above the block.

An apparatus, such as a beam pocket, connects a beam to a wall, such as a concrete wall. The apparatus includes a frame having a plurality of panels that cooperate to define a pocket of various heights. The apparatus includes a clamp within the pocket. The clamp is configured to secure an end of the beam at a position within the pocket. The clamp is further configured to selectively define the position relative to the frame. The apparatus further includes at least one anchor extending from the clamp and away from the pocket for mounting with the wall.

An apparatus, such as a beam pocket, connects a beam to a wall, such as a concrete wall. The apparatus includes a frame having a plurality of panels that cooperate to define a pocket of various heights. The apparatus includes a clamp within the pocket. The clamp is configured to secure an end of the beam at a position within the pocket. The clamp is further configured to selectively define the position relative to the frame. The apparatus further includes at least one anchor extending from the clamp and away from the pocket for mounting with the wall.

An experimental system for out-of-plane seismic performance of a masonry block wall, comprising: a static test bed (1), a lateral limiting system disposed on one side on the static test bed (1), and a transverse load system disposed on the other side on the static test bed (1), a masonry block wall to be tested (401) being disposed between the lateral limiting system and the transverse load system. The experimental system also comprises a vertical load system disposed above a wall. Also provided is an experimental method using the experimental system for out-of-plane seismic performance of a masonry block wall, on the basis of a quasi-static test method, a horizontal reciprocating actuator is used to simulate an out-of-plane seismic load action; quarter-point loading is implemented by means of a multi-stage shear stress distribution apparatus, then a force is transmitted to a second screw rod (602), and the second screw rod (602) fits an out-of-plane uniformly distributed load into four horizontally-equidistant transversely-concentrated forces and transmits same to a test piece. The present invention has the characteristics of a clear force transmission path, uniform stress distribution, high experimental precision and an accurate result, such that the study of the out-of-plane seismic performance of a component is more accurate and reliable.

An experimental system for out-of-plane seismic performance of a masonry block wall, comprising: a static test bed (1), a lateral limiting system disposed on one side on the static test bed (1), and a transverse load system disposed on the other side on the static test bed (1), a masonry block wall to be tested (401) being disposed between the lateral limiting system and the transverse load system. The experimental system also comprises a vertical load system disposed above a wall. Also provided is an experimental method using the experimental system for out-of-plane seismic performance of a masonry block wall, on the basis of a quasi-static test method, a horizontal reciprocating actuator is used to simulate an out-of-plane seismic load action; quarter-point loading is implemented by means of a multi-stage shear stress distribution apparatus, then a force is transmitted to a second screw rod (602), and the second screw rod (602) fits an out-of-plane uniformly distributed load into four horizontally-equidistant transversely-concentrated forces and transmits same to a test piece. The present invention has the characteristics of a clear force transmission path, uniform stress distribution, high experimental precision and an accurate result, such that the study of the out-of-plane seismic performance of a component is more accurate and reliable.

An experimental system for out-of-plane seismic performance of a masonry block wall, comprising: a static test bed (1), a lateral limiting system disposed on one side on the static test bed (1), and a transverse load system disposed on the other side on the static test bed (1), a masonry block wall to be tested (401) being disposed between the lateral limiting system and the transverse load system. The experimental system also comprises a vertical load system disposed above a wall. Also provided is an experimental method using the experimental system for out-of-plane seismic performance of a masonry block wall, on the basis of a quasi-static test method, a horizontal reciprocating actuator is used to simulate an out-of-plane seismic load action; quarter-point loading is implemented by means of a multi-stage shear stress distribution apparatus, then a force is transmitted to a second screw rod (602), and the second screw rod (602) fits an out-of-plane uniformly distributed load into four horizontally-equidistant transversely-concentrated forces and transmits same to a test piece. The present invention has the characteristics of a clear force transmission path, uniform stress distribution, high experimental precision and an accurate result, such that the study of the out-of-plane seismic performance of a component is more accurate and reliable.