A wall block, wall block system and method of making a wall block. The wall block including at least one core extending from the top surface to the bottom surface, the at least one core having opposed front and rear surfaces and first and second side surfaces the wall block also including at least one pin hole opening onto the top surface of the block and extending at least a portion of the distance from the top surface to the bottom surface. The at least one pin hole may open onto at least a portion of at least one surface of the at least one core. The block may be provided with channels; the pin hole, channels and core may all be formed in a mold box by a single forming member.

A wall block, wall block system and method of making a wall block. The wall block including at least one core extending from the top surface to the bottom surface, the at least one core having opposed front and rear surfaces and first and second side surfaces the wall block also including at least one pin hole opening onto the top surface of the block and extending at least a portion of the distance from the top surface to the bottom surface. The at least one pin hole may open onto at least a portion of at least one surface of the at least one core. The block may be provided with channels; the pin hole, channels and core may all be formed in a mold box by a single forming member.

A insulated masonry wall system having insulation blocks between structural and face blocks to provide structures that are strong, inexpensive, avoid thermal bridges, and resist transmission of heat. The walls are attractive and versatile, and an enormous variety of decorative face members may be utilized. The face blocks are attached to the structural blocks to prevent facing materials from falling even if fire destroys the insulation blocks between the structural blocks and the facing. The system resists water penetration and effectively drains water that does penetrate any portion of the system.

The present invention includes a method and a unit for a masonry wall system, each unit comprising a face shell wherein the interior surface has a transverse axis running from the top surface to the bottom surface of the face shell, and one or more webs having a front end and a rear end, wherein the rear end of each web is integral with or attached to the interior surface of the face shell along the transverse axis. The method for wall construction further comprising positioning one or more vertical reinforcement rods or tendons with one end embedded in a wall-foundation and laying a layer wall units on the wall-foundation such that the one or more webs of the layers of wall units are aligned, and the vertical reinforcement rods or tendons run through or are adjacent to the webs of the wall units.

Disclosed is an economical and effective way of producing a double sided wall having a corner or closed end using facing panels having a face surface and a back surface with a retaining structure. The facing panels are stacked in a back-to-back arrangement into a pair of first and second wall components bridged by separate connectors. An end wall component forming an end or corner of the wall includes facing panels stacked to extend across the intermediate space. A branched connector and link are used for bridging a concrete facing panel in the end wall component with an adjacent concrete facing panel of the first or second wall component. The branched connector has a first connecting end and an opposite branched end with at least a pair of second connecting ends for attachment to the retaining structure of the adjacent facing panel and the link has a first end for attachment to a facing panel in the end wall component and a second end for linking to the branched connector.

The present technical solution relates to the field of construction, specifically to constructional wall panels with a window aperture. The technical result is to eliminate thermal bridges, simplify manufacture of. A removable formwork is installed on a vibrating table to form the upper surface 5, the lower surface and two lateral surfaces 6 of the wall panel. Concrete mortar is poured to form the second plate 7. After setting of the concrete mortar and primary hardening, thermal insulation is installed. On the side of the formwork, thermal insulation elements 3 are installed to form a window aperture. Thermal insulation plates are laid on the fourth surface of the second plate 7 to form a second thermal insulation layer 10. The thermal insulation plates are laid at a distance to one another, allowing for cross members and ribs 12 to be formed further.