RU120672U1 - CONSTRUCTION ELEMENT OF INSULATION - Google Patents

Abstract

1. A structural element for thermal insulation between the internal and external structures of buildings and structures, including an insulation made with the possibility of being connected with compression force elements that receive compressive and shear forces, characterized in that the load-bearing elements are made of structural thermal insulation material and have protrusions along the side the ends for joining with the insulation having the corresponding grooves, in the upper part of the power elements there are holes for the passage of the reinforcement of the connecting parts of the building, in the upper and lower surfaces of the structural element there are strip elements made of strong and fire-resistant material and crimping elements made of U-shaped galvanized sheets having slots in the area of the holes for the passage of reinforcement. ! 2. A structural element according to claim 1, characterized in that the insulation can be shifted relative to the compression elements towards the inner structures. ! 3. The structural element according to claim 1, characterized in that the load-bearing elements have a height equal to the thickness of the structures to be joined. ! 4. Structural element according to claim 1, characterized in that the reinforcement is protected from corrosion by the embedding concrete.

Description

The technical solution relates to the field of construction and is intended for the construction of a structural element of thermal insulation between internal and external structures of buildings and structures.

The regulatory literature presents a thermal insulation device in the outer protruding parts of concrete and reinforced concrete structures in the form of effective heaters introduced into them, for example: stoves of unheated loggias and balconies, cornice plates, parapets. At the construction site, prior to concreting the structure, the insulation was installed in reference sections with a certain step, partially reducing the load-bearing capacity of the element (SP 23-101-2000 Design of thermal protection of buildings. FSUE TsPP. M., 2004).

The disadvantages of this design are the presence of heat-conducting sections of heavy concrete, as a result of increased thermal conductivity and wetting of the inner surface of structures, corrosion of steel reinforcement.

Known structural element of thermal insulation (RU 2402659/03, publ. 08/27/2008) for cantilevered balcony slabs, consisting of an insulator and reinforcing elements crossing the insulator and attached to both building parts. As reinforcing elements, elements of the perception of tensile forces and compression forces are provided. Elements of tensile forces are installed in the upper zone of the insulator and protrude horizontally forward relative to the insulator. Elements of compression forces are installed in the lower zone of the insulator. To perceive the transverse force, bent reinforcing bars are installed that intersect the insulator in thickness.

The disadvantage of this design is that the perception of efforts is carried out due to steel reinforcing bars located in the compressed and stretched zones with high thermal conductivity. The contact of reinforcing bars with a heater requires their protection against corrosion due to the formation of water vapor, there is no protection against direct exposure to high temperatures.

The proposed utility model is aimed at reducing metal consumption, labor intensity, costs during transportation and storage, reducing heat loss in the connection while maintaining the bearing capacity, unification of the structural element.

The result is achieved by the fact that in the structural element of thermal insulation between the internal and external structures of buildings and structures, a heater is turned on, made with the possibility of connecting with power elements receiving compressive forces, according to a useful model, the power elements are made of structural and heat-insulating material with protrusions on the side ends for docking with a heater having corresponding grooves, holes are made in the upper part of the compression elements for passing the reinforcement connected of the building, in the upper and lower surfaces of the structural element, strip elements of durable and fire-resistant material and crimping elements of U-shaped galvanized sheets having cutouts in the area of the openings for the passage of reinforcement are installed. The result is also achieved by the fact that the power elements have a height equal to the thickness of the joined structures.

The result is also achieved by the fact that the insulation can be shifted relative to the compression elements towards the internal structure of the buildings to create the air gap required when using ventilated facade systems.

A utility model is illustrated in FIG. 1. The structural element for thermal insulation includes power elements 1 made with protrusions in the side ends and openings for passing reinforcement of the connected parts of the building in the upper plane; the insulation 2 has corresponding grooves for docking with the power elements 1. In the upper and lower parts of the structural element, strip elements of durable and fire-resistant material are laid 3. Galvanized sheets 4 U-shaped on both sides compress the structural element. The top sheet 4 is made with cutouts for the possibility of skipping the reinforcement of the connected building structures and controlling the filling of holes with concrete. In addition, the power elements 1 have a height equal to the thickness of the joined structures. Insulation 2 can be shifted relative to the power elements 1 towards internal structures to create an air gap, thereby providing ventilation of the facade insulation along the entire height of the building.

The device operates as follows. Depending on the current forces and the geometric parameters of the external structures, the device is installed between adjacent supporting reinforced concrete elements in their supporting zones. After the product is installed in the working position, the upper reinforcing bars are passed through the holes in the power elements 1. All joined structures and the thermal insulation device are simultaneously monolithic. Such a constructive solution of the device allows at a minimal cost to create a rigid unit and reduce heat loss.

This device allows you to speed up the process of performing thermal insulation, as it is a prefabricated element of factory manufacture, to reduce the metal consumption by passing longitudinal rods of adjacent structures through the holes of the power elements 1 without overlapping reinforcement joints, and the perception of shear forces by force elements does not require the installation of transverse reinforcement and bends . The absence of protruding reinforcement in the device reduces the complexity of manufacturing, facilitates transportation and storage. The device extends along the length of the construction site by connecting the groove of the insulation 2 with the protruding part of the power element 1. The holes in the power elements allow concrete to flow and envelop the steel reinforcement thereby protecting against corrosion and high temperatures without additional measures.

Under the action of alternating loads on abutting structures and the use of a structural element in the walls, parapets, a hole for passing reinforcement is also arranged at the lower edge of the power element 1.

In addition, the installation of strip elements 3 of a durable and fire-resistant material and galvanized sheets 4 protect the compression elements 1, steel reinforcement and insulation 2 from external influences and give the device spatial rigidity. The configuration of the product in terms of repeats the outlines of connected adjacent structures.

Claims (4)

1. A structural element for thermal insulation between internal and external structures of buildings and structures, including a heater, made with the possibility of connection with the power compression elements that receive compressive and shear forces, characterized in that the power elements are made of structural heat-insulating material and have protrusions on the side the ends for docking with a heater having corresponding grooves, holes are made in the upper part of the power elements for passing the reinforcement of the connected parts of the building In the upper and lower surfaces of the structural element, strip elements of durable and fire-resistant material and crimping elements of U-shaped galvanized sheets having gaps in the area of the openings for the passage of reinforcement are installed. 2. The structural element according to claim 1, characterized in that the insulation can be shifted relative to the compression elements towards internal structures. 3. The structural element according to claim 1, characterized in that the power elements have a height equal to the thickness of the joined structures. 4. The structural element according to claim 1, characterized in that the protection of the reinforcement from corrosion is provided by monolithic concrete.