RU101724U1 - ROOF DEVICE FOR BUILDINGS AND STRUCTURES - Google Patents

Abstract

 The device of the roof of the building and structure, comprising a roof installed on the walls of the building with a gutter located in its lower part, an anti-icing coating made in the form of a thin-walled shell overlapping the space between the upper edge of the gutter and the lower edge of the roof surface with an inlet relative to the lower edge of the roof surface, additional gutter mounted on the roof surface, drainage funnels, characterized in that the additional gutter It becomes not lower roof line adjacency to the inner wall surface of the building, and water taking funnel formed through the roof surface along the upper side of additional gutter.

Description

The invention relates to the field of construction and operation of buildings and structures and can be used to reduce the likelihood of icing and icicles on the edges of the roof.

A device is known for removing from the roof of a building and ice construction (see RF patent for invention No. 2169245, CL 7 E04D 13/00 (published on June 20, 2001, bull. No. 17). The device contains a source of mechanical impulses with a mount on the building or structure and an elastic element located along the eaves of the roof.In addition, the device is equipped with spring-loaded in the opposite direction by mechanical impulses rods, on the one hand connected with an elastic element made in the form of a linear waveguide, mechanically decoupled from the eaves of the roof, on the other hand, with a source of mechanical impulses. Due to the spring-loaded rods in this device, the concentration of the force impulse from the source of its perturbation to the linear waveguide is ensured, thereby increasing the amplitude of the force perturbation transmitted to the icicles. down to earth. The known device contains a number of additional features that improve its technical and operational characteristics.

The device is known for the roof of the building and structures for removing icicles (See copyright certificate No. 775268 according to class E04D 13/06, publ. 30.10.80, bull. No. 40). The device comprises a system of blocks and two shoulders levers pivotally mounted on the corners of the walls of the building. To the ends of the levers are attached cables stretched along the roof. The short ends of the levers are connected by additional cables to a source of mechanical disturbance, for example, doors. The system of levers, blocks and cables allows the use of mechanical forces when opening doors to act on icicles. The known device provides separation and discharge from the roof of already formed icicles due to mechanical energy.

Known devices have solved the problem of facilitating the dropping of icicles formed on the roof. Another area of icicle control involves the use of special roofing coatings, which reduce the likelihood of retaining snow cover on it and, as a result, the formation of ice and icicles.

So, for example, an anti-icing coating is known, which includes non-polar rubbers and can be applied to a surface that is prevented from ice buildup (description of the invention to RF patent No. 2086601 according to Cl. 6 C09K 3/18). The coating can provide effective surface protection for a long period of time from the accumulation of snow on the surface of the roof and the growth of ice. However, to protect the roof from frost and icicles arising on its lower edges, the use of a known coating is expensive and not always effective. So, on sloping roofs, ice may freeze over the entire surface of the roof, the destruction of which can occur only with the growth of large icicles that threaten the safety of the population.

A device is known for the roof of a building and structure, including a roof, the surface of which is de-iced with a strip along the lower edge of the roof, the width of the strip depending on the climatic zone and the slope of the roof is determined by a value from 0.1 m to 2.5 m .; the coating strip is applied with an overlap relative to the roof by an overhang of at least 2 cm down from its lower edge; the angle between the roof surface and the inlet plane does not exceed a value of 180. See RF patent No. 2244790, IPC E04D 13/076

The known technical solution allows to reduce the adhesion of freezing water to the roof surface in its lower part, and thereby reduce the likelihood of frost formation and icicles, or at least reduce the load on the roof during the removal of ice from the roof.

At the same time, taking into account that a significant part of the roofs has a small slope angle, as a result of which, even with insignificant adhesion forces, the ice with the anti-icing coating has cases of ice retention on the roof surface.

The closest technical solution to the proposed one is the device of the roof of the building and structures, containing a roof with an anti-icing coating located in its lower part, made in the form of a thin-walled shell, overlapping the space between the lower edge of the roofing surface with an inlet relative to the lower edge of the roofing upper and upper edge of the gutter, installed relative to the lower edge of the roof surface at a distance of not less than 0.4 m. The height of the gutter is made in size, providing they have an anti-icing gradient of at least 45 °. Gutters installed along the gutter are connected to the water drainage system. In addition, a number of features are provided that increase its effectiveness. See RF patent No. 2338853, publ. November 20, 2008, bull. Number 32.

In this device, the probability of icicles and ice formation on the edge of the roof is significantly reduced due to the integrated solution of the removal of melt water from the roof of the building directly into the city stormwater network, without passing along the cold part of the roof surface that overlaps the eaves of the building. In addition, by increasing the height of the gutter, the angle of the slope of the anti-icing coating at the edge of the roof increases, which reduces the likelihood of snow mass remaining on its surface.

At the same time, the designs of existing buildings and structures are made without taking into account the technical solutions proposed in the known device. Water was removed from the roof surface of existing buildings on the cold surface of a part of the roof, bypassing a cornice protruding outside the building, through receiving funnels extended to the width of the cornice using elbows of drainpipes. In the summer period of operation, the existing water drainage system almost copes with the task. Problems with existing roofs arise in the winter period of operation, when melt water freezes along the path of the protruding cornice. The volume of meltwater compared with summer rainfall is an order of magnitude less. Solving the problem of reducing the likelihood of icing and icicles on existing buildings, in addition to installing the gutter according to the scheme provided for by RF patent No. 2338833, provides for a full cycle of reconstruction of the entire water drainage system from the roof of the building. And the provided drainage system should be designed for the maximum amount of water formed on the roof. This system should ensure the drainage of all waters, including taking into account the maximum possible amount of water formed on the roof during the summer rainfall. The water drainage system, designed to drain melt water generated during the winter period of roof operation, in the summer period, during the period of heavy rainfall, may not cope with water passage, and there is a possibility of overflow of the gutter. The need to increase the installation angle of the anti-icing coating requires an increased height of the gutter. Consequently, the overflow of the gutter will be accompanied by the rise of water on the roof of the building, which increases the likelihood of leaks. Thus, in the well-known technical solution, the drainage system should be designed to discharge precipitation of maximum intensity, the greatest probability of which falls during the seasons with a positive outside temperature, during the period when the probability of icicles formation is practically excluded, which requires increased costs for re-equipping the roof.

The aim of the invention is to reduce the cost of performing work aimed at reducing the likelihood of icing and icicles on existing roofs of buildings.

To achieve the stated goal in the known device of the roof of the building and structure, containing a roof mounted on the walls of the building with a gutter located in its lower part, an anti-icing coating made in the form of a thin-walled shell overlapping the space between the upper edge of the gutter and the lower edge of the roof surface with an inlet relative to the lower edge of the roof surface, an additional gutter installed on the roof surface and drainage funnels, an additional drain installed not lower than the line of abutment of the roof to the inner surface of the walls of the building, and drainage funnels are made through the roof surface, along the upper side of the additional gutter.

The proposed technical solution allows you to use the existing water drainage system for existing roofs of buildings to divert the bulk of the rainfall that falls on the roof during the warm months of operation of the roof. The height of the additional gutter, designed to drain melt water, can be made small, within 1-5 cm, depending on the intensity of the heat flux of the attic and solar radiation, which will ensure that the bulk of the water flows through them and limits the amount of water entering a system of a newly created internal drainage system. Thus, with heavy rainfall during warm periods of roof operation, the proposed technical solution ensures overflow of the additional gutter and the direction of the bulk of the water along the existing water drainage system. In winter, meltwater, formed during the melting of snow masses accumulated on the roof, which make up a small fraction of the bulk of the water, is retained by the upper side of the additional gutter and is discharged through the drainage system through the roof drainage system through the drainage funnels made through the roof surface. Thus, in the proposed technical solution, a significant part of the design of the existing device is stored and used for its intended purpose, which reduces the amount of work on the conversion of existing roofs.

Figure 1 presents the conditional diagram of the proposed technical solution. The device includes a roof 1 with a gutter 2 installed in its lower part and an adjacent funnel 3 of the drainpipe 4. The anti-icing coating 5 is made of sheet material in the form of a thin-walled shell that overlaps the space between the lower edge of the roof 6 and the upper edge of the drainage system gutters 3. The anti-icing coating 5 is made with an inlet relative to the lower edge of the roof 6. The anti-icing coating 3 can be made of various materials. The main requirements for the material are, first of all, tightness and preservation of strength properties under the influence of all loads and dynamic properties. The anti-icing coating can be made both from roofing steel, spring sheet steel, various plastic thin-walled sheets, and from various fabrics, for example, from tent fabrics. (See, for example, http: //www.ttex.rn/ttex/production/pvh/) To enhance the anti-icing properties of the coating, the surface of the coating can be coated with special anti-icing materials, for example, varnishes with Teflon additives or laminated with Teflon film. The fastening of the anti-icing coating 5 on the upper edge of the gutter 2 and the lower edge of the roof 6 can be carried out in accordance with the general design requirements. When using fabrics, fastening can be carried out in a known manner on grommets, by analogy with the fastening of advertising banners, see, for example, RF patent No. 2291261. To prevent sagging of the banner fabric in the space between the upper edge of the gutter 2 and the lower edge 6 of the roof surface, a cable can be tensioned (not shown in the figure). The cable tension can be carried out along a broken line connecting the lower edge 6 of the roof surface with the upper edge of the gutter 2. Known technical solutions can be used to tension and fasten the cable, for example, hooks for fastening to the edge and blocks attached to the hooks through which the cable is passed . An additional gutter 7 is installed not lower than the line of abutment of the roof to the inner surface of the walls of building 8 (on the part of the roof covering the space of the attic). Along the upper side of the additional gutter 7, drainage funnels 9 are installed through the surface of the roof 1, connected to a meltwater drainage system or sewer (not shown in the figure). The height of the additional gutter 7, h, the cross-sectional area of the drainage funnels 9, the frequency of installation of the drainage funnels 9 along the additional gutter 7 is selected by calculating the maximum amount of melt water during the winter period of operation of the roof, based on the roof structure, the angle of inclination of the additional gutter 7 and the degree thermal conditions of the attic. Under conditions of maximum intensity of melting snow masses on the roofing surface at a negative outside temperature (-0 ° C), it is unacceptable to melt water over the upper edge of the additional gutter 9. At the same time, excessive height of the additional gutter can lead to undesirable consequences when the roof is used in summer time period. In the conditions of the summer period of operation of the roof, the excessive height h of the additional gutter can lead to the accumulation of excess water on the roof under heavy rainfall conditions, which will increase the likelihood of leaks. For a significant part of roofs using typical design solutions, the height h is in the range (5-40) mm, the diameter of the drainage funnels (30-100) mm. At the same time, the diameter of the drainage funnels is selected based on the typical sizes of the receiving necks of the drainage funnels and the typical sizes of pipelines and fittings. If it is difficult to find a compromise in determining the optimal height of the additional gutter 7, the additional gutter 7 can be removable, or openings closed for the winter period of operation can be made in the additional gutter (not shown). The area of operational openings and their number, the distance between them are selected based on the specific design features of the roof.

Tracing of melt water discharge from the drainage funnels to the internal drainage system or to the sewage system is carried out within the attic and can be performed in various ways. The main requirement is the tightness of the joints and the provision of conditions for the freezing of melt water formed at negative air temperatures. If it is possible to lay an internal drain in the building, the system tracing can be performed to the internal drain system. In the absence of such a possibility, tracing of the meltwater drainage system is performed into the sewage system (not shown in Fig. 1). Many operating organizations, in order to reduce the likelihood of icicles, by arranging a roof ventilation system, in their zeal go to transforming the roof of the building into a canopy. In such buildings, it may be necessary to carry out additional work to reduce heat loss from the attic. Or to carry out work on the insulation of pipes of the internal drainage system, or pipes connecting the drainage funnels to the sewage system. Since with intense solar heating of the roof slope, even with negative air temperature in the attic, snow may melt, and too much zeal for roof ventilation can lead to freezing of melt water in the pipes between the drain funnel and the internal drainage system, or sewage. With restrictions on the discharge of water into the internal drainage system or sewerage for the summer period, cranes (not shown) can be installed at the entrance to the meltwater drainage system, closed during the summer period of operation of the roof, or during maintenance operations. For ease of operation, cranes can be installed after each discharge funnel 9.

The proposed device operates as follows. Atmospheric precipitation, falling on the roof 1, flows to the additional gutter 7 and through the drain funnels 9 with open taps 10 of the melt water drainage system are removed from the building. With heavy rainfall or closed taps of the meltwater drainage system, water overflows through an additional gutter and enters the gutter 2, then into the funnel 3, the gutter 4 and is diverted from the building according to known technical solutions. With restrictions on the removal of precipitation through the internal drainage system or through the sewer, the valve 10 of the meltwater drainage system and precipitation are closed according to the above scheme through the gutter 2 are removed from the roof. If there is a risk of roof leaks due to overfilling of the additional gutter for the summer period of operation, the additional gutter 7 can be dismantled or special openings can be made in it, eliminating the possibility of overfilling. In winter, with a probable decrease in air temperature to negative values, the roof surface is covered with snow. Snow masses falling on the anti-icing coating 4, due to a significant angle of inclination, wind vibrations of its surface roll down. To reduce the adhesion forces of snow masses, the coating surface, as noted above, can be coated with a special anti-icing compound. In addition, by choosing the height of the gutter, it is possible to achieve an inclination angle of the anti-icing coating, which excludes the retention of snow masses on its surface.

Melt water, formed due to melting of the snow cover of the upper part of the roof due to solar radiation, or heat flows of the under-roof space is delayed by an additional gutter 7 and through gutters 9, open taps (not shown) and the melt water drainage system are diverted from the building. Freezing of melt water in the gutter 3 is prevented by heat flows coming from the under-roof space. Melt water does not fall on the cold surface of the part of the roof that overlaps the overhangs blown by the surrounding cold air, which eliminates the possibility of icicles.

Thus, the proposed technical solution allows you to use the elements of the existing roof structure and its system of water drainage from the roof for the functioning of the roof and the removal of the main precipitation falling on the roof. The volume of roof refinement for the removal of melt water during the winter period of operation of the roof is insignificant, due to the small volume of melt water in the proportion of the bulk discharged from the roof of the water.

The proposed combination of features together with known features can reduce the cost of re-equipping existing roofs to reduce the likelihood of frost and icicles and achieve the objectives of the proposed invention.

Claims (1)

The device of the roof of the building and structure, comprising a roof installed on the walls of the building with a gutter located in its lower part, an anti-icing coating made in the form of a thin-walled shell overlapping the space between the upper edge of the gutter and the lower edge of the roof surface with an inlet relative to the lower edge of the roof surface, additional gutter mounted on the roof surface, drainage funnels, characterized in that the additional gutter It becomes not lower roof line adjacency to the inner wall surface of the building, and water taking funnel formed through the roof surface along the upper side of additional gutter.