RU8014U1 - DRAINAGE DEVICE FROM BUILDING ROOF - Google Patents

Abstract

1. The drainage device from the roof of buildings, including drainpipes and elements supplying water from the roof to the drainpipe (gutters, trays, funnels, etc.), characterized in that the drainpipes and elements supplying water to the drainpipe have sealed cavities, through which a heat carrier flows with a temperature above 273K (0C). 2. The device according to claim 1, characterized in that the sealed cavities of the drainpipe and the elements supplying water to the drainpipe are connected or brought together to each other along a line along the channel of the water drained from the roof. The device according to claim 1, characterized in that the gutter covers the overhang of the roof, and the upper wall of the gutter is inclined towards the roof. The device according to claim 1, characterized in that the design of the drainpipe includes a pipe located inside the drainpipe. The device according to claim 1, characterized in that the design of one or more elements supplying water to the drainpipe includes a pipe adjacent to this element from the side of the water drain. The device according to PP. 1 and 4, characterized in that the pipe included in the design of the drainpipe is made of flexible non-metallic material, for example, rubber-fabric material. 7. The device according to PP. 1 and 5, characterized in that the pipe included in the design of the elements supplying water to the drain pipe is made of a flexible non-metallic material, for example, rubber-fabric material. The device according to claim 1, characterized in that different coolants are used for different elements of the drain, for example, air for the gutter and water for the tray and drainpipe.

Description

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DRAINAGE DEVICE FROM ROOF OF BUILDINGS.

The utility model relates to the construction of buildings, namely to the device of gutters from the roof of buildings, and can be used in residential and industrial buildings.

A device for a drain from the roof of buildings is known, including drain pipes located inside the heated building, and elements supplying water from the roof to the drain pipes (funnels, etc.). 1,2. This design with regular maintenance

provides a steady drain of rain and melt water from the roof. .

A device of a drain from the roof of a building is known, including drain pipes located inside an unheated building, and elements supplying water to a drain pipe 1.

A device for a drain from the roof of a building is known, including drainpipes installed on the extraneous (outer) side of the building, and elements supplying water to the drainpipes 2,3.

The last 2 devices do not provide a steady drain of melt water from the roof, especially during thaws. Melt water flows into the lower part of the roof to the gutter and then to the funnel and downspout, which have a temperature below 273k (Ot), and freezes, forming an ice layer (ice) on the roof of the gutter, on trays and funnels, and ice plugs in downpipes . Melt water flows down from the eaves and overhang of the roof, forming icicles, which is dangerous for people. Known methods of combating ice and ice caps 3 are periodic in nature, require the use of a significant number of workers working in dangerous conditions. However, these methods only slightly mitigate the negative effects. In addition, these methods lead to damage to the roof and drainpipes.

A device for removing snow and ice from the eaves and overhang of the roof, made of flexible elements (for example, part of the car tire) and mounted on the edge of the roof 4. However, this device solves the problem only partially: removal of snow and ice from the overhang of the roof.

The proposed drainage device from the roof of buildings includes drainpipes and elements supplying water from the roof to drainpipes (gutters, trays, funnels, etc.), and drainage pipes and elements supplying water to the drainpipes have closed cavities through which the coolant flows with temperature above

E04D13 06 G

 (OC). Distinctive is that the drainpipes and elements supplying water from the roof to the drainpipes have sealed cavities through which a coolant with a temperature above 273 (013) flows. In buildings where drainpipes are located on the outside (outside) side of the building or inside unheated buildings, melt water flows down the roof to the gutter and further along the gutter, along the trays and funnels (if any) into the gutter. The coolant flows through the cavity of the drainpipe, trays, funnels and gutters and heats them. Melt water near the heated walls does not freeze, providing a steady flow of water from the floor. If melt water freezes on the roof above the gutter, this will not lead to disruption of runoff: the slope of the roof leads to the fact that melt water overflows through the floor and reaches the heated wall of the gutter or funnel.

The connection of the cavities of the drainpipe and the elements leading the water to the drainpipe into an indissoluble line or the convergence of these cavities along the line along the channel of the water drained from the roof contributes to a stable drain of melt water from the roof.

The gutter covers the overhang of the roof, and the upper wall of the gutter is tilted towards 1FOVL, which eliminates the flow of melt water from the overhang of the roof and the possibility of formation of icicles.

The design of the drainpipe includes a pipe located inside the drainpipe, through which the coolant flows. This helps to simplify the design and reduce the cost of the device.

The design of the elements supplying water from the roof to the drainpipe (gutter, tray, etc.) includes a pipe adjacent to these elements through which the coolant flows, which simplifies the design and cost of the device.

The manufacture of the pipe, which is part of the design of the drainpipe and other drainage elements, from a non-metallic flexible material, such as rubber-fabric material, or rubber, or plastic, helps to simplify installation and reduce the cost of the device, especially for buildings with a complex configuration of the outer wall, which are many among the old buildings of St. Petersburg.

The use of different coolants for different drainage elements, for example, warm air for the gutter and water for the funnel and drainpipe, contributes to the rational use of all energy sources, optimization of the design of the drainage elements.

In FIG. 1,2 and 3 show the proposed device (in Fig. 1 is a plan of the device, Fig. 2 is a cross section of the gutter, Fig. 3 is a cross section of a drainpipe):

The device includes a gutter 1 mounted on the roof 2 and covering the overhang of the roof 3, the tray 4, a drainpipe 5, mounted on the outer wall of the building 6. The gutter, the tray and the drainpipe have cavities 7.8 and 9 connected to each other. Through the cavities 7.8 and 9, warm air flows, emitted at the bottom of the drainpipe into the atmosphere. Temperature and air flow depending on design

buildings and devices of the drain and can be determined by calculation according to well-known formulas, based on the fact that the heated walls of the above elements of the drain have a temperature above 2731C (OS). The upper wall 10 of the groove 1 is inclined towards the roof 2. The operation of the device:

During periods when snow melting is expected on roof 2, warm air is supplied in cavities 7.8 and 9, the temperature of the heated walls of the gutter 1, tray 4, and drainpipe 5 rises and is maintained above 273 1С (О t), and thereby creates an inextricable a line for meltwater drainage along the gutter, tray and downspout. At the same time, the snow lying on the upper wall 10 of the gutter 1 melts, and the water flows into the general melt water flow from the roof 2.

In FIG. Figures 4 and 5 show the proposed device (Fig. 4 is a plan of the device, Fig. 5 is a cross-section of the device along B - B): The device includes a gutter 1 mounted on the roof 2, a tray 4 and a downpipe 5 fixed on the outer wall of the building 6 The chute has a cavity 7 through which warm air flows. The design of the tray 4 includes the pipe 11, and the design of the drainpipe includes the pipe 12. The pipes 11 and 12 are connected, and water flows through them (through the cavities 8 and 9). Device operation:

During periods when snow melting is expected on roof 2, warm air is introduced into cavity 7 and water in cavity 8 and 9 of pipes 11 and 12, the temperature of the wall of the groove 1 and the surface of pipes 11 and 12 rises and is maintained higher (Ot), and thereby an inextricable line is created for the drain of melt water along the gutter, tray and along the drainpipe. Air from the cavity 7 is discharged into the atmosphere, and water from the pipes 11 and 12 is discharged into the drain pipe 5 or is discharged by a system that is connected to the pipe 12.

References

1.SNiP 2.04.01-85. Internal water supply and sewerage of buildings. M. 1985, Section 20.

2. Roofs and roofs of buildings and structures. Directory. Kiev. 1988 year

3. Guidelines for the conservation and operation of roofs of residential buildings. Housing Administration of the Executive Committee of the Leningrad City Council. 1957

4. RF patent 2044851 class. E04D

Claims (8)

1. The device of the drain from the roof of buildings, including drain pipes and elements supplying water from the roof to the drain pipe (gutters, trays, funnels, etc.), characterized in that the drain pipes and elements supplying water to the drain pipe have sealed cavities, through which flows a coolant with a temperature above 273 ^o K (0 ^o C).  2. The device according to claim 1, characterized in that the sealed cavity of the drainpipe and the elements supplying water to the drainpipe are connected or brought together to each other along a line along the channel of the water drained from the roof.  3. The device according to p. 1, characterized in that the gutter covers the overhang of the roof, and the upper wall of the gutter is inclined towards the roof.  4. The device according to p. 1, characterized in that the design of the drainpipe includes a pipe located inside the drainpipe.  5. The device according to claim 1, characterized in that the design of one or more elements supplying water to the drain pipe includes a pipe adjacent to this element from the side of the water drain.  6. The device according to paragraphs. 1 and 4, characterized in that the pipe included in the design of the drainpipe is made of flexible non-metallic material, for example, rubber-fabric material.  7. The device according to paragraphs. 1 and 5, characterized in that the pipe included in the design of the elements that supply water to the drain pipe is made of flexible non-metallic material, for example, rubber-fabric material. 8. The device according to claim 1, characterized in that different coolants are used for different elements of the drain, for example air for the gutter and water for the tray and drainpipe.