An improved insulating block that offers great structural strength by having an interconnected block material structure with cavities filled with insulating material. The paths from the front face to the back face of the block through the block material are adapted to ensure an improved thermal insulation of the block, while providing a high load bearing capacity and allowing continuation of longitudinal reinforcement. This results in a block that can be easily manipulated and handled. Furthermore, the invention provides a method of manufacturing and a use of said blocks, and a wall or structure of said blocks.

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.

A construction block (100) including a rigid outer shell (106) and a thermally insulating insert (112). The outer shell (106) defines a pair of outer shell side elements (114, 116) extending substantially vertically and substantially parallel to each other and at least one outer shell transversal element (132) extending between the outer shell side elements (114, 116). The outer shell side and transversal elements (114, 116, 132) are hollow and together define an outer shell cavity (110) delimited by the outer shell (106). The insert (112) is contained inside the outer shell cavity (110).

A construction block (100) including a rigid outer shell (106) and a thermally insulating insert (112). The outer shell (106) defines a pair of outer shell side elements (114, 116) extending substantially vertically and substantially parallel to each other and at least one outer shell transversal element (132) extending between the outer shell side elements (114, 116). The outer shell side and transversal elements (114, 116, 132) are hollow and together define an outer shell cavity (110) delimited by the outer shell (106). The insert (112) is contained inside the outer shell cavity (110).

Environmentally responsible insulating construction blocks and structures constructed primarily of recycled materials are disclosed. The environmentally friendly construction blocks and structures comprise shredded rubber tire pieces coated with silica fume, slag cement and cement, which are then mixed with water and formed in a mold. A layer of grout or a fireproof material may be disposed on one side of the environmentally responsible insulating construction block. The environmentally responsible insulating construction blocks can be used in place of wood blocking for roof assembly applications such as installation of a drip edge or wall coping; or in expansion joints. The environmentally responsible insulating construction blocks provide high insulation as well as strength for applications such as green roofing, wall construction and green roofing decks. Environmentally friendly structures can be built by pouring the coated shredded rubber tire pieces into molds to form walls, and then to pour a layer of the coated shredded rubber tire pieces as a roof deck, thereby creating a self-supporting structure in a monolithic pour.

Environmentally responsible insulating construction blocks and structures constructed primarily of recycled materials are disclosed. The environmentally friendly construction blocks and structures comprise shredded rubber tire pieces coated with silica fume, slag cement and cement, which are then mixed with water and formed in a mold. A layer of grout or a fireproof material may be disposed on one side of the environmentally responsible insulating construction block. The environmentally responsible insulating construction blocks can be used in place of wood blocking for roof assembly applications such as installation of a drip edge or wall coping; or in expansion joints. The environmentally responsible insulating construction blocks provide high insulation as well as strength for applications such as green roofing, wall construction and green roofing decks. Environmentally friendly structures can be built by pouring the coated shredded rubber tire pieces into molds to form walls, and then to pour a layer of the coated shredded rubber tire pieces as a roof deck, thereby creating a self-supporting structure in a monolithic pour.

The invention relates to construction and is intended to create a multilayer structural element that is simple and convenient for combining in a structure and provides minimum shrinkage with the possibility for use in building load-bearing walls, interior partitions, floors and ceilings, as well as for manufacturing prefabricated walls having all process openings by means of bonding and ties during manufacturing; a high-capacity production line for producing a multilayer structural element using equipment consuming low levels of energy; and to enable the supply of vertically oriented exterior elements, as well as a continuous and low-cost method for manufacturing a multilayer structural element. The multilayer structural element includes exterior elements and a heat-insulating layer therebetween. The top and bottom surface of the exterior elements have a longitudinal groove along the entire exterior element. The multilayer structural element enables both horizontal and vertical installation.

Lightweight masonry hollow bricks of a substantially rectangular cuboid shape having central cavities and side indentations. A concrete composition of the masonry hollow bricks includes cement, water, sand, a coarse aggregate, and an insulating material, e.g. perlite, polyethylene, crumb rubber. The developed masonry hollow bricks met the ASTM requirements for non-load bearing masonry bricks in addition to satisfying the ASTM standard as being lightweight masonry bricks.

Lightweight masonry hollow bricks of a substantially rectangular cuboid shape having central cavities and side indentations. A concrete composition of the masonry hollow bricks includes cement, water, sand, a coarse aggregate, and an insulating material, e.g. perlite, polyethylene, crumb rubber. The developed masonry hollow bricks met the ASTM requirements for non-load bearing masonry bricks in addition to satisfying the ASTM standard as being lightweight masonry bricks.