Building blocks include a tongue and groove on each block that allow the blocks to be placed in a way that interlocks the tongue and groove of one block with the corresponding groove and tongue, respectively, of another block facing the opposite direction. In a first embodiment, the same building block that has a decorative front face is used for both sides of the wall, resulting in a wall with opposed finished surfaces. In a second embodiment, a first plurality of blocks that have a decorative front face are used for one side of the wall, while a second plurality of blocks that have a thicker and non-decorative face are used for the other side of the wall, with the first and second plurality of blocks interlocking back-to-back via their respective tongues and grooves. Both types of blocks can be made using the same concrete form.

A mortarless block system for forming walls from blocks which are stackable in sequential rows upon each other. Upper rows of blocks positioned upon lower rows are securable by positioning of support rods through aligned passages thereof. The passages extend between upper and lower notches in each respective block. The support rods are engaged to connectors which are sized to fit completely within the notches to thereby leave the upper and lower surfaces of each lower row flush to stacking overhead rows thereon.

A mortarless block system for forming walls from blocks which are stackable in sequential rows upon each other. Upper rows of blocks positioned upon lower rows are securable by positioning of support rods through aligned passages thereof. The passages extend between upper and lower notches in each respective block. The support rods are engaged to connectors which are sized to fit completely within the notches to thereby leave the upper and lower surfaces of each lower row flush to stacking overhead rows thereon.

An interlocking construction block system comprising a family of blocks that interlock along three axes, including a left/right axis, a front/back axis, and an up/down axis. The family of blocks are self-aligning and do not require skilled labor or mortar to create a structure of any length, width, height, or shape. Each block comprises a specific geometry that allows all blocks in the family to interlock in a woven pattern that not only locks the blocks in place but also allows even distribution of structural weights and stresses. The disclosed blocks can be manufactured in different sizes to conform to any building code requirement and to create wall lengths to a one-inch measurement. The blocks may comprise channel openings to allow for plumbing, electrical, and structural reinforcements in the structure and may each be reinforced with an internal mesh cage.

The invention refers to precast blocks for constructions from which modular elements of insulating material, with optimized geometry are obtained, to a network of channels obtained by assembling the modular elements, to a supporting structure, to a process of obtaining a construction by assembling the modular elements. The precast block for construction, according to the invention, comprises an exterior face provided with recessed areas and protrusions such that the thickness g of the precast block wall is uniform, and fastening areas for veneering elements, considering of ribs set on the protrusions, and/or a surface without recesses and protrusions, obtaining a higher thickness of the precast block wall, for the precast blocks destined to be positioned in the areas where the outer surface of a construction obtained from precast blocks is larger than its inner surface thereof, such that the rate of heat transfer of the construction to be uniform on the entire built surface of said construction, for preventing the occurrence of thermal bridges.

An interlocking construction block system comprising a family of blocks that interlock along three axes, including a left/right axis, a front/back axis, and an up/down axis. The family of blocks are self-aligning and do not require skilled labor or mortar to create a structure of any length, width, height, or shape. Each block comprises a specific geometry that allows all blocks in the family to interlock in a woven pattern that not only locks the blocks in place but also allows even distribution of structural weights and stresses. The disclosed blocks can be manufactured in different sizes to conform to any building code requirement and to create wall lengths to a one-inch measurement. The blocks may comprise channel openings to allow for plumbing, electrical, and structural reinforcements in the structure and may each be reinforced with an internal mesh cage.

A mold set for manufacturing interlocking construction blocks comprising a modular family molds and connecting side walls. The molds may be configured to create assembled female molds that may be filled with fluid cement, which can be removed from the female molds with corresponding male molds. Each assembled female mold may comprise one or more interlocking sections that allow the resulting blocks to interlock in three directions along three axes, including a left/right axis, a front/back axis, and an up/down axis. Each block comprises a specific geometry that allows all blocks in the family to interlock in a woven pattern that not only locks the blocks in place but also allows even distribution of structural weights. The disclosed modular mold sets allow blocks to be manufactured in different sizes to conform to any building code requirement and to create wall lengths to a one-inch measurement.

An interlocking construction block system comprising a family of blocks that interlock along three axes, including a left/right axis, a front/back axis, and an up/down axis. The family of blocks are self-aligning and do not require skilled labor or mortar to create a structure of any length, width, height, or shape. Each block comprises a specific geometry that allows all blocks in the family to interlock in a woven pattern that not only locks the blocks in place but also allows even distribution of structural weights and stresses. The disclosed blocks can be manufactured in different sizes to conform to any building code requirement and to create wall lengths to a one-inch measurement. The blocks may comprise channel openings to allow for plumbing, electrical, and structural reinforcements in the structure and may each be reinforced with an internal mesh cage.

A method for building a mechanical secured block structure, including placing a footer block on a desired surface, inserting two respective starter bar nuts into the footer block, inverting the footer block, placing a first concrete masonry unit over respective first and second anchor bars, aligning the first concrete masonry unit with the footer block, placing second and third footer blocks adjacent the first footer block, placing a second concrete masonry unit adjacent the first concrete masonry unit, positioning each respective concrete masonry unit to equally straddle two adjacent footer blocks, positioning respective anchor bars atop respective concrete masonry units, and bolting respective concrete masonry units to respective footer blocks to interconnect the two respective concrete masonry units and the three respective footer blocks to define a contiguous wall. Each respective masonry unit and each respective footer block are post tensioned to be under compression.

The invention refers to precast blocks for constructions from which modular elements of insulating material, with optimized geometry are obtained, to a network of channels obtained by assembling the modular elements, to a supporting structure, to a process of obtaining a construction by assembling the modular elements. The precast block for construction, according to the invention, comprises an exterior face provided with recessed areas and protrusions such that the thickness g of the precast block wall is uniform, and fastening areas for veneering elements, considering of ribs set on the protrusions, and/or a surface without recesses and protrusions, obtaining a higher thickness of the precast block wall, for the precast blocks destined to be positioned in the areas where the outer surface of a construction obtained from precast blocks is larger than its inner surface thereof, such that the rate of heat transfer of the construction to be uniform on the entire built surface of said construction, for preventing the occurrence of thermal bridges.