A dry-stack masonry wall supported on hollow piles includes a wall having a plurality of stacked rows of masonry blocks that form a hollow interior grid of horizontal and vertical channels. The wall is supported on piles having hollow interiors, each of which is in communication with one of the vertical channels of the wall. Hardened grout filling the grid of the wall and the interiors of the piles monolithically binds the blocks into a wall which is bonded to and supported by the piles.

A rectangular block having a front surface, a rear surface, a bottom surface, a top surface defined by a pair of lengthwise edges and a pair of side edges connecting the lengthwise edges, the rectangular block including: a first channel disposed along a left side surface, the first channel extending in a direction from the front surface to the rear surface; and a second channel along a plane parallel to the left side surface, the plane disposed at an offset distance from the left side surface, the second channel extending in a direction from the front surface to the rear surface, wherein the left side surface is configured to be positionable so as to mate with a left side surface of an adjacently disposed block to form a full channel to receive a rebar, whereby walls are constructible from a plurality of such blocks.

The present invention generally relates to a precision dry-stack masonry unit made of two spaced-apart face shells and at least one connector joining the face shells. The connector has a top surface, a right surface and a left surface. The top surface of the connector and the face shells form a horizontal channel above the connector, and the right surface and the left surface of the connector and the face shells form vertical channels to each side of the connector. Each of the channels is configured to accommodate one or more reinforcement bars.

The present invention generally relates to a precision dry-stack masonry unit made of two spaced-apart face shells and at least one connector joining the face shells. The connector has a top surface, a right surface and a left surface. The top surface of the connector and the face shells form a horizontal channel above the connector, and the right surface and the left surface of the connector and the face shells form vertical channels to each side of the connector. Each of the channels is configured to accommodate one or more reinforcement bars.

A theft-proof packaging system includes a product package including a compartment configured to encapsulate a product. The compartment is in a non-surrounding environmental state, the non-surrounding environmental state being either pneumatically pressurized above a surrounding environment or pneumatically vacuumized below the surrounding environment. A pressure sensor inside the compartment includes a switch, the switch configured to disconnect and connect a power source to a transmitter, wherein the switch is configured to disconnect the power source from the transmitter in the presence of the non-surrounding environmental state inside the compartment and the switch is configured to connect the power source to the transmitter when the compartment equalizes to the surrounding environment. A receiving unit is disposed remote from the product package and receives the signal from the transmitter and sounds an alarm. A passive RFID tag may be located within the compartment and detected when passing through a walk-through scanner.

A modular superblock assembly includes interconnectable and stackable insulating concrete forms that each comprise a block body. The block body includes a central mounting hole, a first lateral recess, second lateral recess, first vertical recess, second vertical recess, and aligning features. The first lateral recess traverses a first lateral side of the block body. The second lateral recess traverses a second lateral side of the block body. The first vertical recess traverses a first vertical side of the block body. The second vertical recess traverses a second vertical side of the block body. The central mounting hole traverses the lateral recesses and is oriented perpendicular thereto. The plurality of aligning features includes aligning plates and slots. Each aligning plate is partially embedded in a first surface of the block body and positioned proximate to the first lateral recess. Aligning slots are positioned on the first surface.

A modular superblock assembly includes interconnectable and stackable insulating concrete forms that each comprise a block body. The block body includes a central mounting hole, a first lateral recess, second lateral recess, first vertical recess, second vertical recess, and aligning features. The first lateral recess traverses a first lateral side of the block body. The second lateral recess traverses a second lateral side of the block body. The first vertical recess traverses a first vertical side of the block body. The second vertical recess traverses a second vertical side of the block body. The central mounting hole traverses the lateral recesses and is oriented perpendicular thereto. The plurality of aligning features includes aligning plates and slots. Each aligning plate is partially embedded in a first surface of the block body and positioned proximate to the first lateral recess. Aligning slots are positioned on the first surface.

A wall construction system including plurality of interlocking concrete blocks. The interlocking blocks include one or more stretcher blocks, corner blocks, and half blocks. The blocks include top and end shear lugs and bottom and end grooves. The bottom grooves accommodate the top shear lugs of blocks in a lower course of stacked blocks. Corner blocks provide a means for creating a corner and turning the direction of a course of blocks by 90 degrees. The interlocking features of the blocks enable dry-stacking in successive courses to construct a wall or multi-wall structure. When stacked end to end in successive rows, the top and end shear lugs of each interlocking block engage complimentary grooves in the underlying, overlying, and adjacent blocks thereby enabling the blocks to rapidly self-align vertically and lock together as they are stacked. The resulting dry-stacked structure exhibits a high lateral resistance to overpressures or transverse loads.

The set of modular timber hollow bricks with thermal insulation properties includes wooden hollow bricks, marked as A and B which have a box structure. Hollow brick A and corner hollow brick B include two boards connected by crossbars in such a way, that they form a peripheral socket on the inside for a connection with the connector. The corner hollow brick B also has a connector on the side surface of the board. Each hollow brick has a circumferential socket, the size of which corresponds to half the thickness of the connector. The corner hollow brick B has a notch on the lateral surface. The hollow brick A and corner hollow brick B have each an additional reinforcing bar inside. The socket is filled with sealing foam before assembly.

The set of modular timber hollow bricks with thermal insulation properties includes wooden hollow bricks, marked as A and B which have a box structure. Hollow brick A and corner hollow brick B include two boards connected by crossbars in such a way, that they form a peripheral socket on the inside for a connection with the connector. The corner hollow brick B also has a connector on the side surface of the board. Each hollow brick has a circumferential socket, the size of which corresponds to half the thickness of the connector. The corner hollow brick B has a notch on the lateral surface. The hollow brick A and corner hollow brick B have each an additional reinforcing bar inside. The socket is filled with sealing foam before assembly.