RU145917U1 - MONOLITHIC OUTDOOR WALL FOR SMALL BUILDING - Google Patents

Abstract

1. A monolithic outer wall for a low-rise building, inside of which, by the height of the concrete layer, inserts of heat-insulating material with a coefficient of thermal conductivity from 0.028 to 0.09 W / (m · ° C) are located, each of which is enclosed in a vapor-tight shell, characterized in that the wall has an angular shape and additionally contains reinforcing meshes installed along the height of the concrete layer along the outer and along the inner surfaces of the angular wall structure and interconnected by transverse couplers made of glass plastic, and further comprising a self-regulating heating cable, placed vertically in the corner of the wall, and as vapor tight envelope for each insert truba.2 plastic used. Monolithic outer wall according to claim 1, characterized in that it is made of expanded clay concrete. The monolithic outer wall according to claim 1, characterized in that the reinforcing mesh is installed at a distance of 50 mm from the outer and inner surfaces of the angular wall structure.

Description

The utility model relates to the field of ground construction, and more specifically to the outer corners of buildings erected in a monolithic way, and can be used in areas with a cold climate for low-rise buildings.

A known construction of a building panel is presented in the patent RU 2033507. The building panel includes the longitudinal channels formed therein, the rod and its spirally located reinforcement. Each coil of the spiral is made in the form of a hexagon. The turns of each adjacent spiral are located between the turns of another spiral with the formation of gaps. The channels are formed vertically in a staggered manner congruent to the coils of the reinforcement. The construction panel has enhanced performance properties.

The disadvantage is the large number of difficult to manufacture fittings and low thermal resistance. To ensure the required thermal resistance, it is necessary to place insulating inserts in the longitudinal channels that are not provided for by the construction of the building panel in accordance with RU 2033507.

The prototype for the claimed utility model is the technical solution presented in patent RU 49067 U1 E04G 11/08, 2005. Inside the monolithic concrete wall along the height of the concrete layer, heat-insulating inserts are made of heat-insulating material with a thermal conductivity of 0.028 to 0.09 W / (m · ° C), and each of the inserts has an outer vapor-tight layer, for example polymeric. The inserts can be in the section of any shape: round, rectangular, etc. In special cases of execution, the wall declared as a utility model can be constructed from expanded clay concrete, and the inserts from expanded polystyrene. The design of a monolithic concrete wall according to the prototype has a high resistance to heat transfer and eliminates the penetration of water vapor into the insulating inserts. The imperfection of the prototype is the insufficient bearing capacity of the structure being built and the likelihood of condensation on the inner surface of the wall at low negative temperatures.

The objective of the claimed utility model is to increase strength and improve the thermal characteristics of the building structure.

The technical result consists in creating optimal microclimate parameters in a room by eliminating the formation of condensate on the inner surface of monolithic walls and increasing the heat transfer resistance of the wall at the same time as increasing the bearing capacity of the wall.

The problem is solved as follows.

The monolithic external wall for a low-rise building, like the prototype, contains inside the height of the concrete layer of the insert from the insulating material with a thermal conductivity of 0.028 to 0.09 W / (m · ° C). Each insert is enclosed in a vapor-tight shell.

Unlike the prototype, the claimed wall has an angular shape. It additionally contains reinforcing mesh installed along the height of the concrete layer along the outer and along the inner surfaces of the angular wall structure, for example at a distance of 50 mm from them. Reinforcing meshes are interconnected by transverse couplers made of fiberglass. In addition, the claimed monolithic wall further comprises a self-regulating heating cable placed vertically in the corner of the wall. A plastic pipe was used as a vapor tight shell for each insert.

A monolithic external wall in a particular case can be made of expanded clay concrete.

Thus, in order to achieve the specified technical result, inside the monolithic concrete wall along the height of the concrete layer, to reduce the thermal conductivity of the wall and increase the vapor tightness, vertical insulation inserts made of heat-insulating material with a thermal conductivity coefficient from 0.028 to 0.09 W / (m · ° C), enclosed in plastic pipe. Near the inner corners, linear vertical heat sources are installed in the form of a heating self-regulating cable. To increase the bearing capacity of the structure under construction, steel reinforcing mesh is used, built at a distance of 50 mm from the inner and outer surfaces of the corner structure and interconnected with fiberglass ties.

Due to the fact that fiberglass reinforcement is laid across the wall, the specific gravity of the structure is reduced, and the effective thermal conductivity of the wall is reduced. At the same time, such reinforcement is characterized by ease of installation, sufficient strength and lower price.

As a result of the fact that a steel reinforcing mesh is laid along the wall surfaces, and a self-regulating heating cable is built in the inner corner of the structure, the claimed utility model in comparison with the prototype increases the load-bearing capacity of the wall, increases its energy efficiency and eliminates the possibility of condensation in the corners. Inserts in the form of plastic pipes with insulation (thermal insulation material) in comparison with the prototype have better vapor impermeability, more durable and convenient for the construction of monolithic walls.

The essence of the utility model is illustrated in the drawing. The drawing shows a monolithic concrete wall in plan. Heat-insulating inserts 2, reinforcing mesh 3, interconnected by couplers of fiberglass 4, and a self-regulating heating cable laid in the corner 5 are installed in the monolithic expanded clay concrete wall 1.

The utility model is industrially applicable. The proposed technical solution can be implemented using well-known equipment and well-known construction technologies. For the manufacture of the wall, metal formwork is used, with the help of which the necessary thickness of the wall and cavity of the required volume are formed. As insulating inserts, factory-made plastic pipes of a certain diameter, filled with a heater made, for example, of expanded polystyrene, are used. First, a removable or non-removable formwork is installed, then a reinforcing mesh is inserted into it and fixed. After that, insulating inserts are placed inside the formwork and the entire structure is poured with concrete.

Claims (3)

1. A monolithic outer wall for a low-rise building, inside of which, by the height of the concrete layer, inserts of heat-insulating material with a coefficient of thermal conductivity from 0.028 to 0.09 W / (m · ° C) are located, each of which is enclosed in a vapor-tight shell, characterized in that the wall has an angular shape and additionally contains reinforcing meshes installed along the height of the concrete layer along the outer and along the inner surfaces of the angular wall structure and interconnected by transverse couplers made of glass plastic, and further comprising a self-regulating heating cable, placed vertically in the corner of the wall, and as vapor tight envelope for each insert used plastic pipe. 2. The monolithic outer wall according to claim 1, characterized in that it is made of expanded clay concrete. 3. The monolithic outer wall according to claim 1, characterized in that the reinforcing mesh is installed at a distance of 50 mm from the outer and inner surfaces of the angular wall structure.