RU134562U1 - BUILDING ROOF HEATING SYSTEM - Google Patents

Abstract

The solution relates to the field of construction, in particular to devices for removing snow and / or ice from the roof of a building. The technical result of the proposed solution is to reduce the complexity of manufacturing and installing the device. The system is designed to melt snow, prevent ice formation, reduce snow load during heavy snowfalls at ambient temperatures ranging from + 5 ° C to -15 ° C, and also to heat operated roofs mainly at ambient temperatures ranging from -5 ° C up to + 20 ° C. In the coldest regions, it is also possible to use the proposed system. The heating system of the roof of the building, including the working body, interacting with the roof of the building, is characterized in that the working body is a network of pipelines located in the roof structure, either on the roof itself, or in drainpipes and gutters, heated working fluid, and the network of pipelines connected to a heat source. The system is characterized by the fact that, through a network of pipelines, the working fluid enters the distribution unit, which serves to distribute it through the pipelines. The system is characterized in that it consists of ready-made modules. The system is also characterized in that the diameter of the pipeline network is at least 8 mm, the distance between the pipelines can be from 1 to 500 mm. 1 n.p. f-ly, 2 ill.

Description

The solution relates to the field of construction, in particular to devices for removing snow and / or ice from the roof of a building.

Known devices are designed to remove icicles from the roof of a building, and they can be divided into two groups: moved on the roof and installed permanently.

The main disadvantages of movable devices for removing icicles from the roof of the building are the complexity and increased risk to the safety of the worker regardless of the design of the device (RF patent for the invention No. 2215857, class E04D 13/076, publ. 10.11.2003).

The indicated drawback is deprived of devices for removing icicles from the roof of a building, which are installed permanently with fastening on a wall or a cornice of a building.

A device for removing icicles is known, in which a system of blocks and two-arm levers pivotally mounted on the corners of the walls of the building is provided. 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, such as 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 (copyright certificate of the Russian Federation for the invention No. 775268, class E04D 13/06, publ. 10/30/1980).

The disadvantage of this device is the involuntary removal of icicles, which can lead to injuries to people who are currently near the building.

A device for removing icicles from the overhangs of the roof of a building, including a knocking body, a cable for moving a knocking body, a system of rotary blocks and equipped with a guide fixed to the wall of the building along the roof, made in the form of a pipe and playing the role of a carrier (RF patent for invention No. 2209905, class E04D 13/076, published on 08/10/2003).

The disadvantage of this device is the design complexity, a high probability of icing of the cable moving knocking body and the guide, which can lead to the cessation of the device.

A device is known for removing ice from the eaves of roofs of buildings and structures, including a source of mechanical impulses and an elastic element interacting with it in the form of a waveguide of metal profiles fixed along the eaves of the roof (RF patent for the invention No. 2169245, class E04D 13/00, publ. 06/20/2001).

A device for removing icicles from the roof of a building is known, which contains a source of mechanical vibrations made in the form of an electric rotation drive and a flexible waveguide interacting with it, consisting of a body made in the form of a flexible tube and a metal cable that can rotate through an internal hole the case along its entire length (RF patent for the invention No. 2452830, class E04D 13/076, publ. 10.06.2012).

The latter invention can be taken as the closest solution, including a working body that interacts with the roof of the building.

A limitation of this invention is that it is quite laborious in the manufacture and installation of the device.

The technical result of the proposed solution is to reduce the complexity of manufacturing and installing the device.

The system is designed to melt snow, prevent ice formation, reduce snow load during heavy snowfalls at ambient temperatures ranging from + 5 ° C to -15 ° C, and also to heat operated roofs mainly at ambient temperatures ranging from -5 ° C up to + 20 ° C. In the coldest regions, it is also possible to use the proposed system.

A network of pipelines with a diameter of 8 mm located both in the roof structure and on the roof itself or in the drain pipes and gutters through which the heated working fluid (coolant) circulates, which has a positive temperature of +5 to + 100 ° C, is proposed. depending on the required load.

1, 2 shows the proposed system, the numbers indicate: 1 - heat source, 2 - main pipeline, 3 - distribution unit, 4 - network of pipelines, 5 - pump. It is unprincipled which roof is served by the system - flat or pitched (Fig. one).

The roof structure is usually laid by the architect when developing project documentation, the AR section (architectural solutions), and pipelines are built into the structure depending on the composition and operating conditions of a particular roof, for which all necessary calculations are carried out and the project is developed.

The distance between the pipelines can be from several mm to 500 mm - it depends on the heat load, which is calculated during the development of the project, and the roof structure.

It is possible to connect a piping network to a central or local heating system.

It is promising to use ready-made modules with pipelines covering, for example, an area of 1000 × 1000 mm.

Any known coolant with a freezing temperature below the calculated minimum for the specific region in which the system is used is used as a working fluid.

The system can be connected to any known heat source designed to heat the working fluid (for example: gas, liquid and solid fuel boilers, electric heaters, heat exchangers, etc.).

Operating principle.

The working fluid (heat carrier) is heated (receives energy) in any possible heat source (1), whether it is heat received through a heat exchanger, for example, from central heating systems, or from a boiler powered by electricity, on gaseous, liquid or solid fuel.

Further, through the main pipelines (2), the working fluid enters the distribution unit (3), for example, a collector, from where it is distributed through the pipelines of the roof heating system (4).

The heated working fluid moves through the pipelines of the roof heating system (4) and gives off the accumulated thermal energy through the walls of the pipelines, then to the roof structures, from which the surface or accumulated snow and / or ice is heated.

After that, the cooled coolant enters the heat source (1) through the distribution unit (3), through main pipelines (4).

The coolant in the system is circulated by the pump (5).

The system of circulation of the working environment is closed.

With sufficient heating, snow and / or ice passes from a solid state to a liquid state, after which it flows or evaporates, depending on operating conditions.

Claims (4)

1. The heating system of the roof of the building, including a working body that interacts with the roof of the building, which is a network of pipelines through which heated working fluid circulates with the help of pumps, and the network of pipelines is connected to a heat source, characterized in that the pipeline network is located in the roof structure. 2. The system according to claim 1, characterized in that through the network of pipelines, the working fluid enters the distribution unit, which serves to distribute it through the pipelines. 3. The system according to claim 1, characterized in that it consists of ready-made modules. 4. The system according to claim 1, characterized in that the diameter of the pipeline network is at least 8 mm, the distance between the pipelines can be from 1 to 500 mm.

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