RU95708U1 - METAL ROOF - Google Patents

Abstract

 1. Metal roof, including upper and lower profiled flooring mainly with trapezoidal corrugations, thermal insulation, anti-condensation film and discrete elements supporting along the roof run and connected to it through the lower profiled flooring, located with the formation of a ventilated space under the upper profiled flooring, characterized in that each supporting element is made in the form of a trapezoidal section in profile with lower flanged flanges for its fastening to the run installed above the corrugation of the lower profiled flooring, and the upper profiled floor is laid on a metal crate located in a ventilated space and consisting of upper and lower elements, between which an anti-condensation film is placed, while each lower element is installed along the roof slope on the shelves coaxially located on adjacent runs supporting elements and is made in the form of a channel-shaped profile in cross section, and the upper element adjacent to the upper profiled deck has a hat pro s, the slope is perpendicular, wherein between the surfaces anticondensation insulation film and a gap is formed. ! 2. The metal roof according to claim 1, characterized in that the thermal insulation along the height of the roof section is made with different densities, at a height not exceeding half the height of the support element from the upper profiled flooring, the thermal insulation density is higher than in the rest of the zone. ! 3. The metal roof according to claim 1, characterized in that a term is installed between the flanges of the support element and the lower profiled flooring

Description

The utility model relates to the field of construction, in particular, to the construction of a metal flat or low-slope up to 10% ventilated roof for buildings for various purposes, made of upper and lower profiled flooring, mainly of a trapezoidal shape with thermal insulation placed between them.

Known metal two-layer roof, consisting of upper and lower profiled metal flooring with trapezoidal corrugations and heat insulation and supporting parts placed between them. Each supporting part consists of two elements: an L-shaped elongated element made of a heat-insulating material, one side adjacent to the lower floor, and a Z-shaped metal element, which is a support for the upper floor and resting on the upper surface of the L-shaped element. (GB 2198464, 1988).

The implementation of one of the elements of the supporting part from the heat-insulating material minimizes the transfer of cold temperature from the upper flooring to the lower one, however, the complex shape of the part increases the labor required for the manufacture of the roof, and the low strength of the heat-insulating element compared to the metal profile, which is the place of abutment of the upper flooring, can lead to crushing support, and, therefore, worsen the performance of the roof.

The closest analogue to the proposed technical solution is a two-layer metal roof, including upper and lower profiled flooring, mainly with trapezoidal corrugations, and heat insulation and supporting elements placed between them, discretely installed along the roof run and connected to it through the lower profiled flooring (RU 2101430, 1998).

A disadvantage of the known roof is the difficulty of manufacturing a support element consisting of two parts: two metal brackets installed in pairs along the corrugations of the upper and lower decks, installed in pairs by the shelves. When using two parts of the same shape, the upper and lower decks, one of which is bearing and the other enclosing, must have the same corrugated outline, which increases the metal consumption of the roof. In addition, the anti-condensation film laid directly on the thermal insulation does not provide ventilation of the insulation and makes it difficult to remove moisture from it, and the work of a thin top flooring according to the point-supported scheme reduces the rigidity of the roof.

The task to which the utility model is directed is to eliminate the above disadvantages.

The technical result of the utility model is to increase the bearing capacity of the roof, improve its heat-insulating properties and simplify installation.

This problem is solved due to the fact that in the metal roof including the upper and lower profiled decking, mainly with trapezoidal corrugations, thermal insulation, anti-condensation film and discrete supporting elements discretely installed along the roof run and connected to it through the lower profiled decking, which form a ventilated space under the upper profiled flooring, each supporting element is made in the form of a trapezoidal section in profile with lower flanged flanges for it to It is connected to the run and installed above the corrugation of the lower profiled flooring, and the upper profiled floor is laid on a metal crate located in a ventilated space and consisting of upper and lower elements, between which an anti-condensation film is placed, with each lower element installed along the roof slope coaxially on the shelves located on adjacent runs of the supporting elements and is made in the form of a channel-shaped profile in cross section, and the upper element adjacent to the upper profiled flooring, and has a hat profile, is perpendicular to the slope, and a gap is formed between the surfaces of the anti-condensation film and the thermal insulation.

In a metal roof, thermal insulation along the height of the roof section can be performed with different densities; at a height not exceeding half the height of the support element from the upper profiled flooring, the insulation density is higher than in the rest of the zone.

Thermal insulating gaskets are installed in the metal roof between the flanges of the support element and the lower profiled flooring.

In a metal roof, the upper element of the metal lathing is connected to the lower element through an anti-condensation film.

The top profiled flooring is made with a polymer coating.

In the metal roof, supporting elements are located along each crossbar with a step equal to the length of at least two corrugations of the lower profiled sheet.

The invention is illustrated by drawings, which depict:

- figure 1 is a longitudinal section of the roof;

- figure 2 is a transverse section of the roof.

The metal roof is flat or slightly sloping with an inclination angle not exceeding 10%. The roof consists of two layers of profiled flooring: upper 1 and lower 2. Corrugations of the upper and lower floorings can be made with any shape - from sinusoidal to rectangular, but mainly with a trapezoid shape. The cross section of the upper and lower decks, which determines the height of the corrugations and their pitch, can be different. If the upper flooring is carried by the carrier, the height of its corrugations is greater than the height of the corrugations of the lower flooring. The top profiled floor 1 can be made with a polymer coating.

The lower profiled flooring 2 is laid on the roof girders 3 of the roof, which can be made of a bent Z-shaped or C-shaped profile or any other rolling profile, the cross section of which is assigned according to the calculation depending on the current roof loads.

The corrugations of the upper 1 and lower 2 decks are oriented in the same direction along the roof slope, and the runs 3 are located perpendicular to the corrugations of the decks.

Supporting elements 4 are located along each run through 2-3 corrugations of the lower profiled flooring.

Each supporting element 4 is made in the form of a trapezoidal cross-sectional profile, the free ends of the side walls 5 of which are flanged at a right angle to the outside with the formation of flanges 6 for its fastening to the run 3.

The supporting element 4 is installed above one of the corrugations of the lower profiled flooring so that its smaller base 7 is located above the shelf of this corrugation, the side walls are oriented along the walls of the corrugation, and its flanges 6 are located in depressions located on both sides of the corresponding corrugation.

Thermal insulation 7 is laid on the bottom profiled sheet, mainly from light heat-insulating materials with a bulk density not exceeding 300 kg / m ³ in the form of boards made of polyurethane foam or expanded polystyrene. Plates can be faced with fiberglass.

The height of the support element 4 exceeds the height of the insulation 7.

The upper profiled floor 1 rests on a metal crate, consisting of upper 8 and lower 9 elements connected to each other, between which an anti-condensation film 10 is placed.

The lower molded element 9 is installed along the slope of the roof and is a bent channel-shaped profile in cross section. The wall 11 of the channel-shaped 11 profile is installed through a heat-insulating gasket 12 on the shelves 13 of the supporting elements aligned with adjacent runs, and its shelves 14 cover the lateral inclined walls 5 of these supporting elements.

The shape of the lower element 9 of the metal crate ensures the fixation of the supporting elements 4 located along one axis due to the entry of their upper parts into the cavity of the channel-shaped element, which simplifies the installation of the roof structure.

The upper element 8 adjacent to the upper profiled flooring 1 has a hat profile and is located perpendicular to the plane of the roof slope and parallel to the run.

The fastening of the upper element 8 to the lower 9, as well as the fastening of the anti-condensation film 10 is carried out by fixing threaded elements passed through the bends of the hat profile, which facilitates the installation of the roof.

The support of the upper profiled flooring 1 on the elements of the battens mutually perpendicular in terms of the plan can provide a high load-bearing capacity of the roof, and the form of the elements of the battens can reduce the labor costs for installation.

Elements of the metal crate are placed in the ventilation space 15 located under the upper profiled floor 1. At the same time, an air gap 15 is formed between the lower surface of the anti-condensation film 10 and the upper surface of the thermal insulation 7, which allows water vapor penetrating through the thermal insulation to spread above the thermal insulation to be distributed over the surface of the anti-condensation film followed by the removal of water vapor by an air stream under the upper roof deck.

Between the flanges of the support element and the lower profiled floor installed heat-insulating gaskets 12, preventing the formation of condensate on the inner surface of the lower profiled floor.

The installation of the roof is as follows.

According to the roof runs, located at a distance L from each other and made in the form of a Z-shaped or C-shaped profile, a lower profiled flooring is installed on the self-tapping screws. At the same time, to the roof runs through 2-3 corrugations of the lower profiled floor, the supporting elements are fixed in the form of a trapezoidal section in the section, with a height exceeding the insulation height laid on the lower profiled floor. After laying the thermal insulation, a metal crate is installed. First, on the supporting elements placed on adjacent girders along one axis parallel to the roof slope, the lower linear elements of the battens having a channel-shaped profile in cross section are installed through heat-insulating gaskets. The shelves of the lower elements of the lathing are turned towards the lower floor, so that the upper parts of the supporting elements are placed in the cavity of the lower elements of the lathing, fixing their position. An anti-condensation film is laid on top of the lower elements of the crate, followed by fixing to them. Then, install the upper elements of the lath having a hat profile. Each upper element is installed perpendicular to the slope coaxially to the supporting elements located on the run and attached by fasteners passed through the bends of the hat profile to the lower element of the crate through an anti-condensation film.

Sheets of profiled flooring are laid on top of the crate. At the same time, the crate is placed in the ventilation space formed under the upper profiled flooring, and an air gap of about 50 mm is formed between the anti-condensation film and the insulation, which provides insulation ventilation and moisture removal.

The connection of profiled sheets of flooring with each other is "overlapped". The connection of the profiled flooring to the girders is carried out by means of self-tapping screws with a sealing washer.

Claims (6)

1. Metal roof, including upper and lower profiled flooring mainly with trapezoidal corrugations, thermal insulation, anti-condensation film and discrete elements supporting along the roof run and connected to it through the lower profiled flooring, located with the formation of a ventilated space under the upper profiled flooring, characterized in that each supporting element is made in the form of a trapezoidal section in profile with lower flanged flanges for its fastening to the run installed above the corrugation of the lower profiled flooring, and the upper profiled floor is laid on a metal crate located in a ventilated space and consisting of upper and lower elements, between which an anti-condensation film is placed, while each lower element is installed along the roof slope on the shelves coaxially located on adjacent runs supporting elements and is made in the form of a channel-shaped profile in cross section, and the upper element adjacent to the upper profiled deck has a hat pro s, the slope is perpendicular, wherein between the surfaces anticondensation insulation film and a gap is formed. 2. The metal roof according to claim 1, characterized in that the thermal insulation along the height of the roof section is made with different densities, at a height not exceeding half the height of the support element from the upper profiled flooring, the thermal insulation density is higher than in the rest of the zone. 3. The metal roof according to claim 1, characterized in that between the flanges of the support element and the bottom profiled floor installed insulating gaskets. 4. The metal roof according to claim 1, characterized in that the upper element of the metal crate is connected to the lower element through an anti-condensation film. 5. The metal roof according to claim 1, characterized in that the upper profiled flooring is made with a polymer coating. 6. The metal roof according to claim 1, characterized in that the supporting elements are located along each crossbar with a step equal to the length of at least two corrugations of the lower profiled sheet.