RU92059U1 - VENTILATED ROOF (OPTIONS) - Google Patents

Abstract

1. A ventilated roof, characterized in that inside it between its respective layers there is a rigid three-dimensional spatial lattice, the channels of which freely communicate with the external atmosphere at the bottom and at the top of the roof through exhaust pipes. ! 2. The ventilated roof according to claim 1, characterized in that the rigid spatial three-dimensional lattice is made of two grids located parallel to the gap (at some distance relative to each other) and interconnected by rods so that channels filled with air are formed, freely communicating with external atmosphere. ! 3. The ventilated roof according to claim 1, characterized in that the rigid spatial three-dimensional lattice is made of threads randomly intertwined. ! 4. The ventilated roof according to claim 1, characterized in that the rigid spatial three-dimensional lattice is made of threads randomly interwoven with each other and fastened on both sides at the intersection with layers of durable waterproof material. ! 5. The ventilated roof according to claim 1, characterized in that the rigid spatial three-dimensional lattice is made of separate interconnected mats, panels or rolls. ! 6. The ventilated roof according to claim 1, characterized in that the rigid spatial three-dimensional lattice is attached to the base by fasteners. ! 7. The ventilated roof according to claim 1, characterized in that it is made of separate mats, panels or rolls fastened together. ! 8. A ventilated roof including successively laid on a sloping base and bonded layers of vapor barrier, thermal insulation and waterproofing, as well as arranged between

Description

The utility model relates to the field of construction and repair of buildings and can be implemented when roofing buildings for any purpose.

It is known that currently widely used are ventilated roofs, which, depending on the functional purpose of buildings, are constructed with or without insulation (see F.A. Blagoveshchensky, E.F. Bukina, "Architectural Structures", Moscow, Architecture - C , 2007, pp. 120-122, 211-212; “Construction of roofs with rolled and mastic roofs”, translated from the Czech G.V.Shevalov, edited by A.N. Masonov, Moscow, 1984, p. 10, 120).

For roofs without insulation, especially for flat roofs, roll material made of vulcanized polymers is often used as a coating. Roofing using these materials is attached directly to the base with adhesive. During the operation of the roof, condensation of water vapor occurs in the space under the roof covering. Under the influence of vapor pressure, both the separation of the roofing from the base and the local (point) breakthrough of the roofing sheet can occur. To remove water vapor, it is necessary that the roof base has a proper slope, and also provide ventilation under the roof space by creating ventilation ducts under the roof covering that are connected to the ventilation hoods installed on the roof. However, the known construction of roofs without insulation with the installation of ventilation ducts in them is distinguished by complexity, high complexity and the cost of their manufacture.

In particular, the invention “Ventilated roofing” according to the patent of the Russian Federation No. 2079615 is known, relating to a roof without insulation and adopted by us as a prototype for our utility model “Ventilated roofing (Variants)” relating to a variant of a roof without insulation. The essence of this prototype invention for the construction of a roof without insulation is as follows. On the base of the roof roll roofing material is glued only in certain areas (points). To do this, cut pieces of about 150 mm in length from a roll of double-sided adhesive tape, the average width of which is 100 mm, and paste them onto the roof base in a checkerboard pattern at the rate of one piece of tape per 2 square meters of the base. Then, evenly unwinding the roll of roofing material, glue it to the pieces (plates) of adhesive tape already placed on the base. To ensure reliable adhesion of the surfaces to be glued, the roofing material is loaded at the place of gluing. Since the adhesive tape has a thickness of 0.8-1.2 mm, air channels are formed between the roofing and the base of the roof, which collect water vapor and move it to the ventilation hoods. The disadvantage of the device of the ventilation channels according to this patent is the high complexity of manufacturing. Moreover, all operations are carried out in the conditions of construction on the roof of the building. In addition, due to the high hydraulic resistance of the channels, the effective removal of water vapor and moisture from the roofing is not ensured.

Instead of roofs without insulation for residential and industrial buildings, as a rule, roofs with insulation are used (see F.A. Blagoveshchensky, EF Bukina, "Architectural Structures", Moscow, Architecture - S, 2007, p. 120 -122, 211-212; “Construction of Roofs with Roll and Mastic Roofs”, translated from Czech G.V. Shevalov, edited by A.N. Masonov, Moscow, 1984, p. 10, 120). These roofs consist of successively laid on the base of the vapor barrier layer, insulation and waterproof layer. In this case, the insulation is protected from moisture by water vapor contained in the air of the premises, a layer of vapor barrier material, placing it on the inner (lower) side of the insulation. And to remove water vapor and moisture that has got into the insulation for some reason, ventilation ducts are arranged between it and the inner surface of the outer (waterproofing) layer of the roofing. In addition, a vapor-permeable windproof material can be placed over the insulation to remove water vapor from the thickness of the insulation and protect the insulation from destruction.

If the outer roof layer is formed by slate, tile, etc., and the waterproofing layer is arranged under this layer, then a ventilation gap is also arranged between the outer roof layer and the outer surface of the waterproofing layer. The device ventilation gaps allows you to eliminate condensate, which usually accumulates on the inner surface of the outer layer of the roof and on the inner surface of the waterproofing layer. In the latter case, the device of the ventilation ducts eliminates the wetting of the heat-insulating layer, because of which the latter loses its heat-insulating properties and, in addition, when wet, its weight and the corresponding load on the roof base increase. However, in known constructions of roofs with insulation, the arrangement of ventilation ducts in them leads to a noticeable complication of structures, an increase in the complexity and cost of their manufacture.

In particular, the ventilated roof according to the patent SU 836314 is known, containing successively laid layers of thermal insulation, screeds and waterproofing, as well as a network of ventilation ducts connected via main-collector channels or a channel with an exhaust pipe. In this case, the network of ventilation ducts is made in a screed over which perforated roll material is placed. The disadvantage of the device of the ventilation channels according to this patent is the high complexity of manufacturing. Moreover, all operations are carried out in the conditions of construction on the roof of the building. In addition, due to the high hydraulic resistance of the channels, the effective removal of water vapor and moisture from the roof layers and its heat-insulating properties are not provided.

The utility model “Ventilated roof” according to RF patent No. 46788, which we accept as a prototype for our utility model “Ventilated roof (options)” for a variant of a ventilated roof with insulation, is also known. The ventilated roof according to this patent consists of layers of thermal insulation, screed and waterproofing and a network of ventilation ducts connected to the exhaust pipe successively laid on the roof base. Between the base and the insulation layer there is a vapor barrier layer. Through-holes are made in the screed, and strips of synthetic material are laid in mutually perpendicular directions along the screed. At the same time, the latter overlap the through holes in the screed. The network of ventilation ducts is formed by gluing strips of synthetic material to the screed and gluing waterproofing, while the waterproofing in the places of laying the synthetic material is not glued. The disadvantage of the device of the ventilation channels according to this patent is the high complexity of their device. Moreover, all operations are carried out in the conditions of construction on the roof of the building. In addition, due to the high hydraulic resistance of the channels, the effective removal of water vapor and moisture from the roof layers is not ensured and, accordingly, its heat-insulating properties are not provided.

A common drawback of known ventilated roofs, both without insulation and with insulation, is the high complexity of the ventilation ducts and the fact that all ducting operations are carried out under construction conditions on the roof of the building, as well as structural difficulties with ensuring low hydraulic resistance of the ventilation ducts, allowing you to effectively remove water vapor and moisture from the layers of the roof.

The task to which the proposed group of utility models is directed is to reduce the laboriousness of the device of the ventilation ducts, as well as to ensure their low hydraulic resistance, which allows efficient removal of water vapor and moisture from the roof layers.

The stated technical problem is solved by the fact that in the ventilated roof between its respective layers there is a rigid three-dimensional spatial lattice, the channels of which freely communicate with the external atmosphere at the bottom and at the top of the roof through exhaust pipes. This lattice can consist of two grids located parallel to the gap (at a certain distance) relative to each other and interconnected by rods so that longitudinal and transverse channels filled with air are formed, freely communicating with the external atmosphere. Also, a three-dimensional spatial lattice can be made of threads randomly intertwined. These threads can be fastened on both sides at the points of intersection with layers of durable waterproof material. Bonding on both sides at the points of intersection with the layers of this material can be carried out thermally. The grill may adhere to the underlying layer of the roof or to its base. It can also be attached to them with fasteners. The hydraulic resistance to vapor removal of the three-dimensional three-dimensional lattice is small, and its various sizes, including the thickness of the lattice, provide the necessary ventilation. A feature of the spatial three-dimensional lattice is the possibility of its industrial production in the form of mats, panels or rolls, which significantly reduces its cost, and also simplifies the roof structure, reduces labor costs and the cost of its construction.

Thus, the essence of the proposed options for the “Ventilated Roof” utility model is that in this roof for ventilation between its respective layers there is placed a rigid three-dimensional spatial lattice manufactured in the form of mats, panels or rolls, the channels of which freely communicate with the external atmosphere as below the roof, and above through the exhaust pipes.

Moreover, in the embodiment of a ventilated roof without insulation, which is proposed as a utility model, an industrially manufactured three-dimensional lattice is placed directly on the base of the roof to which it can be glued or fastened with fasteners. A rigid three-dimensional spatial lattice can be made of separate, interconnected, mats, panels or rolls. A roofing waterproofing material is placed on top of the grate and attached to it - the outer covering of the roof. The channels of a rigid spatial three-dimensional lattice freely communicate with the external atmosphere at the bottom of the roof and at the top of the roof through exhaust pipes and provide adequate ventilation of the space between the base and the inner surface of the outer roof covering. The ventilated roof can be made of separate mats, panels or rolls fastened together. This design of a ventilated roof is simple, and the labor and cost of its manufacture are relatively small.

In the embodiment of a ventilated roof with a heater proposed as a utility model, an industrially manufactured three-dimensional spatial lattice is placed between the insulating and waterproofing layers. For the option of placing a layer of vapor-permeable windproof material over the insulation, which allows water vapor to be removed from the thickness of the insulation and protect the insulation from destruction, a three-dimensional grating is placed between the layer of vapor-permeable windproof material and the waterproofing layer. Rigid spatial three-dimensional lattice and in these variants can be made of separate, interconnected, mats, panels or rolls. A waterproofing material is placed on top of the grate and attached to it - the outer covering of the roof. The channels of a rigid spatial three-dimensional lattice freely communicate with the external atmosphere at the bottom of the roof and at the top of the roof through exhaust pipes and provide adequate ventilation of the space between the heat-insulating and waterproofing layers. For the option of placing a layer of vapor-permeable windproof material over the insulation, it provides adequate ventilation of the space between the layer of vapor-permeable windproof material and the waterproofing layer. The ventilated roof can be made of separate mats, panels or rolls fastened together. This design of options for a ventilated roof with insulation is simple to manufacture, and the labor and cost of its manufacture are relatively small.

In the embodiment of the ventilated roof, which is proposed as a utility model, with a heater and an outer roof covering installed above the waterproofing layer, industrially manufactured three-dimensional gratings are placed between the thermal insulation layer and the inner surface of the waterproofing layer, as well as between the outer surface of the waterproofing layer and the inner surface of the outer roof covering. For the option of placing a layer of vapor-permeable windproof material over the insulation, which allows water vapor to be removed from the thickness of the insulation and protect the insulation from destruction, a three-dimensional grating is placed between the layer of vapor-permeable windproof material and the waterproofing layer. Rigid spatial three-dimensional lattice and in these variants can be made of separate, interconnected, mats, panels or rolls. The channels of a rigid spatial three-dimensional lattice freely communicate with the external atmosphere at the bottom of the roof and at the top of the roof through exhaust pipes and provide proper ventilation of the space between the heat-insulating layer and the inner surface of the waterproofing layer, as well as ventilation of the space between the outer surface of the waterproofing layer and the inner surface of the outer roof covering. The ventilated roof can be made of separate mats, panels or rolls fastened together. This design of a ventilated roof with insulation is simple to manufacture, and the labor and cost of its manufacture are relatively small.

An experimental test of the possibility of ventilation through the channels of a three-dimensional three-dimensional lattice confirmed their low hydraulic resistance. Thus, the possibility of practical application of the proposed options for the construction of a ventilated roof and the reduction of labor costs and the cost of their manufacture is confirmed.

Claims (35)

1. A ventilated roof, characterized in that inside it between its respective layers there is a rigid three-dimensional spatial lattice, the channels of which freely communicate with the external atmosphere at the bottom and at the top of the roof through exhaust pipes. 2. The ventilated roof according to claim 1, characterized in that the rigid spatial three-dimensional lattice is made of two grids located parallel to the gap (at some distance relative to each other) and interconnected by rods so that channels filled with air are formed, freely communicating with external atmosphere. 3. The ventilated roof according to claim 1, characterized in that the rigid spatial three-dimensional lattice is made of threads randomly intertwined. 4. The ventilated roof according to claim 1, characterized in that the rigid spatial three-dimensional lattice is made of threads randomly interwoven with each other and fastened on both sides at the intersection with layers of durable waterproof material. 5. The ventilated roof according to claim 1, characterized in that the rigid spatial three-dimensional lattice is made of separate interconnected mats, panels or rolls. 6. The ventilated roof according to claim 1, characterized in that the rigid spatial three-dimensional lattice is attached to the base by fasteners. 7. The ventilated roof according to claim 1, characterized in that it is made of separate mats, panels or rolls fastened together. 8. A ventilated roof, including successively laid on a sloping base and bonded to each other layers of vapor barrier, thermal insulation and waterproofing, as well as ventilation ducts arranged between the thermal insulation and waterproofing layers, freely communicating with the external atmosphere at the top and bottom of the roof, characterized in that for ventilation between the insulating and waterproofing layers there is a rigid spatial three-dimensional lattice, the channels of which freely communicate with the external atmosphere as below effect, and the top of the roof through the exhaust pipe. 9. The ventilated roof according to claim 8, characterized in that the rigid spatial three-dimensional lattice is made of two grids located parallel to the gap (at a certain distance relative to each other) and interconnected by rods. 10. The ventilated roof according to claim 8, characterized in that the rigid spatial three-dimensional lattice is made of threads randomly intertwined. 11. The ventilated roof according to claim 8, characterized in that the rigid spatial three-dimensional lattice is made of threads randomly interwoven with each other and fastened on both sides at the intersection with layers of durable waterproof material. 12. The ventilated roof of claim 8, characterized in that the rigid spatial three-dimensional lattice is made of separate interconnected mats, panels or rolls. 13. The ventilated roof according to claim 8, characterized in that the rigid spatial three-dimensional lattice is attached to the base by fasteners. 14. The ventilated roof according to claim 8, characterized in that it is made of separate mats, panels or rolls fastened together. 15. A ventilated roof, including successively laid on a sloping base and bonded to each other layers of vapor barrier, heat insulation, steam and windproof material and waterproofing, as well as ventilation ducts arranged between the layer of steam and windproof material and waterproofing layer, freely communicating with the outside atmosphere below and at the top of the roof, characterized in that for ventilation between the layer of steam and windproof material and a waterproofing layer is placed kaya three-dimensional spatial lattice channels which communicate freely with the outside atmosphere both below the roof and at the top through the exhaust pipe. 16. The ventilated roof according to claim 15, characterized in that the rigid spatial three-dimensional lattice is made of two grids located parallel to the gap (at a certain distance relative to each other) and interconnected by rods. 17. The ventilated roof according to claim 15, characterized in that the rigid spatial three-dimensional lattice is made of threads randomly intertwined. 18. The ventilated roof according to claim 15, characterized in that the rigid spatial three-dimensional lattice is made of threads randomly interwoven with each other and fastened on both sides at the intersection with layers of durable waterproof material. 19. The ventilated roof according to claim 15, characterized in that the rigid spatial three-dimensional lattice is made of separate interconnected mats, panels or rolls. 21. The ventilated roof according to claim 15, characterized in that the rigid spatial three-dimensional lattice is attached to the base by fasteners. 22. The ventilated roof according to claim 15, characterized in that it is made of separate mats, panels or rolls fastened together. 23. A ventilated roof, including successively laid on a sloping base and bonded to each other layers of vapor barrier, thermal insulation, waterproofing and external coating, as well as ventilation ducts arranged between the thermal insulation and waterproofing layer and between the waterproofing layer and the external coating, freely communicating with the external atmosphere below and at the top of the roof through exhaust pipes, characterized in that for ventilation between these layers there are three-dimensional spatial lattices, the channels of which are one in communication with the outside atmosphere both below the roof and at the top through the exhaust pipe. 24. The ventilated roof according to claim 23, characterized in that the rigid spatial three-dimensional lattice is made of two grids located parallel to the gap (at a certain distance relative to each other) and interconnected by rods. 25. The ventilated roof according to item 23, wherein the rigid spatial three-dimensional lattice is made of threads randomly intertwined. 26. The ventilated roof according to claim 23, wherein the rigid spatial three-dimensional lattice is made of threads randomly interwoven with each other and fastened on both sides at the intersection with layers of durable waterproof material. 27. The ventilated roof according to item 23, wherein the rigid spatial three-dimensional lattice is made of separate interconnected mats, panels or rolls. 28. The ventilated roof according to item 23, wherein the rigid spatial three-dimensional lattice is attached to the base by fasteners. 29. The ventilated roof according to claim 23, characterized in that it is made of separate mats, panels or rolls fastened together. 30. A ventilated roof, including successively laid on a sloping base and bonded with each other layers of vapor barrier, heat insulation, vapor and windproof material, waterproofing and an external coating, as well as arranged between a layer of vapor and windproof material and the inner side of the waterproofing layer and between the outer side waterproofing layer and external coating ventilation ducts that freely communicate with the external atmosphere at the top and bottom of the roof through exhaust pipes, excellent yuschayasya in that for ventilation between these layers has three-dimensional spatial lattice channels which communicate freely with the outside atmosphere both below the roof and at the top through the exhaust pipe. 31. The ventilated roof according to claim 30, characterized in that the rigid spatial three-dimensional lattice is made of two grids located parallel to the gap (at a certain distance relative to each other) and interconnected by rods. 32. The ventilated roof according to claim 30, characterized in that the rigid spatial three-dimensional lattice is made of threads randomly intertwined. 33. The ventilated roof according to claim 30, characterized in that the rigid spatial three-dimensional lattice is made of threads randomly interwoven with each other and fastened on both sides at the intersection with layers of durable waterproof material. 34. The ventilated roof according to claim 30, wherein the rigid spatial three-dimensional lattice is made of separate interconnected mats, panels or rolls. 35. The ventilated roof according to claim 30, characterized in that the rigid spatial three-dimensional lattice is attached to the base by fasteners. 36. The ventilated roof according to claim 30, characterized in that it is made of separate mats, panels or rolls bonded together.