UA125499U - COMPOSITE INSULATING BRIDGE FOR COMBINED PROFILE DESIGNED FOR WINDOWS, DOORS AND FRONT ELEMENTS - Google Patents

Abstract

Composite insulating jumper for the combined profile, intended for the manufacture of window, door and facade elements, consisting of metal parts and at least one thermal insulation layer, extended in the longitudinal direction and having at least two longitudinal edges for rolling into one of the sections of the profile, transverse to a certain distance and adapted to rigidly shift the connection to the parts of the combined profile. The metal parts of the composite insulating jumper have at least one side facing each other, cavities forming cavities filled with a material with a thermal conductivity of less than 0.16 W / m · Κ and a tensile strength greater than 135 N / mm2, and a thermal insulation layer is formed from this material, the metal parts having no mechanical and thermal contacts.

Description

The useful model belongs to the insulating jumper for the combined profile, intended for window, door and facade elements.

Insulating jumpers for combined profiles for window, door and facade elements and combined profiles for window, door and facade elements are known, for example, from publications OE 29623019 01 (ER 0829609 VI), CE 19735702 AT, CE 29821183 01 (ER 1004739

B1), CE 19956415 SI, CE 19818769 A1 and OE 19853235 A1. From the publication OE 19818769 A1, an insulating jumper consisting of plastic and a metal insert embedded in it is known.

The metal insert and plastic have notches, thanks to which the bridge has a lattice (step) structure. The metal insert serves to prevent the complete failure of the insulating jumper in the event of a fire. Notches in the metal insert are designed to reduce thermal conductivity. Such a technical solution has several disadvantages, which are associated with additional mechanical or other types of processing of the extruded heat-insulating bridge blank, which leads to an increase in the cost of this element and the combined profile as a whole. Also, the materials used in the production of this heat-insulating jumper are of petroleum origin, which is an exhaustive resource of the planet Earth.

A large number of inventions are also known (EP 2551436 A1, EP 2241711 A1, CM201306092), where the heat-insulating jumper is made of a polymer material that has insufficient heat resistance in the event of abnormal situations associated with a significant thermal impact on structures made of a combined profile. This can lead to the destruction of structures made of such a combined profile.

The useful model is based on the task of creating an insulating jumper (a thermally insulating jumper or insert, also called a thermal bridge or a thermal gap) for a combined profile, which would allow obtaining a sufficiently high shear stiffness (shear stiffness) with improved thermal insulation, ensuring high thermal resistance and using materials , subject to regeneration.

The task is solved by the fact that in a composite insulating jumper for a combined profile intended for the manufacture of window, door and facade elements, consisting of metal parts and at least one heat-insulating layer, which is elongated in the longitudinal direction and has at least two longitudinal edges for

By rolling into the grooves of the parts of the combined profile, separated from each other in the transverse direction by a certain distance and adapted for shear-rigid connection with the parts of the combined profile, according to a useful model, the metal parts of the composite insulating bridge have at least one of the sides located facing each other, protrusions are depressions that form cavities, which are filled with a material with a thermal conductivity of less than 0.16 W/m K and a compressive strength of more than 135 N/mm, and form a heat-insulating layer from this material, at the same time, the metal parts do not have mechanical and thermal contact with each other.

According to a useful model, in order to ensure sufficient strength and shear stiffness of the composite insulating bridge, the protrusions and depressions of the metal parts of the latter have such a shape that ensures the load of the material of the thermal insulation layer in shear and/or compression.

According to a useful model, to ensure sufficiently low heat transfer between the metal parts of the composite insert, the material of the thermal insulation layer is an epoxy composition that forms a foam.

According to a useful model, in order to provide sufficiently high thermal resistance to withstand the high thermal loads characteristic of fires, the material of the thermal insulation layer is a fire-resistant epoxy composition that forms a foam.

According to a useful model, to ensure sufficient strength and shear stiffness, sufficiently low heat transfer between metal parts, and high heat resistance of the composite insulating bridge, the material of the thermal insulation layer is a foam-forming alloy.

According to the useful model, to ensure strength and rigidity while reducing the mass and overall characteristics of the heat-insulating insert, the material of the metal parts is a three-dimensional nanostructured alloy. In addition, nanostructured alloys have increased heat transfer resistance.

According to the useful model, to ensure the installation of additional elements of the combined profile: seals, fastening elements, etc., the outer surfaces of the metal parts may have additional protrusions/recesses.

A useful model is explained in the following drawing, which shows a composite insulating jumper 60 for a combined profile intended for window, door and facade elements, consisting of metal parts (1) and at least one heat-insulating layer (2), which is elongated in the longitudinal direction and has at least two longitudinal edges (3) for rolling into the grooves of the parts of the combined profile, separated from each other in the transverse direction by a certain distance and adapted for shear-tight connection with the parts of the combined profile. The metal parts of the composite insulating bridge have, on at least one of the sides facing each other, protrusions-hollows (4) that form cavities, which are filled with heat-insulating material, from which a heat-insulating layer is formed.

Thus, the proposed design of the composite insulating jumper allows to obtain a sufficiently high shear stiffness with improved thermal insulation, high thermal resistance and the use of materials subject to regeneration.

Claims (7)

USEFUL MODEL FORMULA 1. Composite insulating jumper for a combined profile intended for the manufacture of window, door and facade elements, consisting of metal parts and at least one heat-insulating layer, which is elongated in the longitudinal direction and has at least two longitudinal edges for rolling into the grooves of the parts of the combined profile, spaced apart from each other in the transverse direction at a certain distance and adapted for a shear-rigid connection with parts of a combined profile, which is characterized by the fact that the metal parts of the composite insulating bridge have at least one of the sides located facing each other, protrusions-recesses, that form cavities that are filled with a material with a thermal conductivity of less than 0.16 W/m-K and a compressive strength of more than 135 N/mm-, and form a heat-insulating layer from this material, while the metal parts do not have between mechanical and thermal contact. 2. Composite insulating jumper for a combined profile intended for the manufacture of window, door and facade elements, according to claim 1, which is characterized by the fact that the protrusions and depressions of the metal parts of the composite insulating jumper have such a shape that ensures the shear load of the material of the thermal insulation layer and/or compression. Zo 3. Composite insulating jumper for a combined profile intended for the manufacture of window, door and facade elements, according to claim 1 and/or according to claim 2, which is characterized by the fact that the material of the thermal insulation layer is an epoxy composition that forms foam. 4. Composite insulating jumper for a combined profile intended for the manufacture of window, door and facade elements, according to claim 1 and/or according to claim 2, and/or according to claim 3, which differs in that the material of the thermal insulating layer is a fire-resistant epoxy composition, which foams. 5. A composite insulating jumper for a combined profile intended for the manufacture of window, door and facade elements, according to claim 1 and/or according to claim 2, and/or according to claim 3, and/or according to claim 4, which differs in that the material of thermal insulation layer is a foam-forming alloy. b. Composite insulating jumper for a combined profile intended for the manufacture of window, door and facade elements, according to claim 1 and/or according to claim 2, and/or according to claim 3, and/or according to claim 4, and/or according to claim 5, which differs the fact that the material of the metal parts is a three-dimensional nanostructured alloy. 7. Composite insulating jumper for a combined profile intended for the manufacture of window, door and facade elements, according to claim 1 and/or according to claim 2, and/or according to claim 3, and/or according to claim 4, and/or according to claim 5, and/or according to claim 6, which is characterized by the fact that the outer surfaces of the metal parts have additional protrusions/recesses for mounting additional elements of the combined profile: seals, fastening elements, etc.