RU72247U1 - SYSTEM FOR REMOVING THE SNOW AND NALEDIA FROM ROOF OF BUILDINGS - Google Patents

Abstract

1. A system for removing snow and ice from the roof of a building, comprising a pipeline leading to the roof connected at one end to a fan, and a heater, characterized in that the heater is made in the form of a flow radiator, the ends of which are built into the pipe of the heating system that is led into the attic, while the radiator is installed in the attic between the fan and the pipeline. 2. The system according to claim 1, characterized in that a pipe connected to the exhaust channel of the building is connected to the radiator. The system according to claim 1, characterized in that the pipeline led to the roof is connected to at least one pipe oriented along the roof with at least one nozzle. The system according to claim 3, characterized in that the pipeline oriented along the roof is located on the outer surface of the roof and / or near its inner surface. The system according to claim 3, characterized in that at least one pipeline located on the roof is made with a blind end. The system according to claim 3, characterized in that the pipeline oriented along the roof is flexible. The system according to claim 2, characterized in that it comprises a housing in which a fan, a radiator and an outlet end of a pipe connected to the exhaust duct of the building are installed. The system according to claim 7, characterized in that the inner surface of the housing is made with thermal insulation.

Description

This utility model relates to the field of construction and can be used in the arrangement of roofs of buildings and structures to protect them from the negative effects of snow masses. The utility model is applicable for arranging roofs of various structures of such structures as sports palaces, indoor stadiums, swimming pools, factory floors and residential buildings, including for membrane roofs and for hinged roofs.

In those climatic zones in which the winter season is accompanied by heavy snowfalls, there is a problem of removing snow cover from the roofs of buildings and preventing their icing. The appearance of ice and the accumulation of significant snow masses on the roof leads to an increase in mechanical loads on the roof elements, which causes a reduction in their service life and failure of their components, and water retention on the roof surface during the autumn-spring period and during thaws causes leaks and damage to the premises located under the roof. Reduces the service life of roofs and the need for mechanical cleaning of the roof, which is carried out in order to avoid separation of ice masses, which creates a real danger to people's lives and often leads to significant material damage (damage to vehicles, underlying architectural elements).

Currently, along with the development of building structures that provide for special technical solutions that reduce the likelihood of accumulation of large snow masses on the roofs, much attention is also paid to the development of inexpensive and effective systems applicable for the protection of buildings in operation with various roof structures and configurations. The main elements of such systems are roof-mounted heating elements (for example, JP 5052066, 1993.03.02) and pipelines through which, as a rule, coolant is passed under high pressure - hot water, heated air or steam.

The efficiency of using heating elements and pipelines with hot water is determined by the density of laying of heating elements and pipelines on the roof surface, and the desired increase in laying density leads to an increase in the mechanical load on the roof, contributes to the formation of icicles and increases the likelihood of a roof collapse. For these reasons, it is more promising to use heated air (steam) to remove snow and ice from roofs.

Known technical solutions using heated air (steam) to blow the roof. Pipes equipped with nozzles are used for this purpose, the nozzles being either located at the outlet ends of the pipelines (e.g., JP 9296630, 1997.11.18) or distributed along the length of the pipelines (e.g. JP 3212576, 1991.09.18). Pipelines are installed stationary (for example, DE 202006007850 U, 2006.08.31) or with the possibility of moving along the outer surface of the roof (JP 2006283515, 2006.10.19); they can

be made closed or with muffled ends (for example, JP 2003082881, 2003.03.19)

A known system in which high temperature steam or air (≥300 ° C) is used to heat an element in the form of a cover mounted on a roof on a support (JP 2006291583, 2006.10.26). The lower part of the element blown by heated air is made of a material that generates infrared radiation, and the outer surface is made of insulating material.

The disadvantages of the known systems include the need for autonomous heating of water or air to a sufficiently high temperature, which complicates the heat supply system of the building and significantly increases the energy consumption for its operation.

This utility model is a system for removing snow and ice from roofs, combined with equipment for heat supply and ventilation of buildings, which reduces energy costs for the operation of the building.

Known technical solutions aimed at removing snow and ice from roofs by supplying air to the roof from ventilation ducts. For the distribution of air over the roof surface, special devices installed on it are used, for example, in the form of hoods whose edges do not touch the roof (JP 6294190, 1994.10.21), pipelines connected to the building’s ventilation duct supplying warm air to the roof (for example, US 5836344, 1998.11.17).

The closest analogue of the claimed system is a system known by JP 2002309802, 2002.10.23, which avoids the formation of snow massifs on the roof by blowing steam over the outer surface of the roof. The system includes a fan connected to a pipeline that removes the heated steam from the heater, and a pipe that leaves the fan, connected to a roof-mounted pipeline with openings through which air enters the roof. In addition, in the attic there is a pipeline, one end of which is connected to the ventilation duct of the building, and the other is connected to the fan.

The main disadvantage of this system is the use of steam as a coolant, which has a negative effect on the roof structural elements located in the attic, thereby shortening its life. In addition, to remove snow from roofs of large surfaces, this system requires several heaters, which increases energy consumption.

The technical result achieved by using the inventive system is to ensure effective removal of snow and ice from the roofs of buildings without harmful influence of the coolant on the structural elements of the roof in the attic and to ensure a stable microclimate in the attic that is optimal for the operation of the roof, which increases its lifetime .

The obtained technical result ensures the applicability of the claimed system for roofs of large area and various designs having different types of coatings.

In addition, the obtained technical results are low energy consumption and easy installation.

In accordance with the utility model, a system for removing snow and ice from the roof of a building, comprising a pipeline leading to the roof connected at one end to a fan, and a heater, characterized in that the heater is made in the form of a flow radiator, the ends of which are built into the pipe brought into the attic heating system, while the radiator is installed in the attic between the fan and the pipeline.

In addition to the radiator, a pipe connected to the exhaust duct of the building can be supplied.

It is advisable to connect the pipeline to the roof with at least one pipe oriented along the roof with at least one nozzle.

The pipeline oriented along the roof can be located on the outer surface of the roof and / or near its inner surface.

It is also advisable to at least one oriented along the roof of the pipeline with a blind end.

The pipeline oriented along the roof can be flexible.

To increase the efficiency of the system, it is desirable to install a fan, a radiator and an outlet end of a pipe connected with the exhaust duct of the building in the housing. In this case, the inner surface of the housing, it is advisable to perform with thermal insulation.

Various system options are possible, differing in the number and location of pipelines oriented along the roof surface, the material from which they are made (rigid or flexible), the form of execution (in the form of closed pipelines or as a set of sections, each of which is equipped with a plug). They can be located both on the roof and in the attic in close proximity to the inner surface of the roof. When using a large number of such pipelines, their combined placement is possible: part - on the roof, and part - in the attic. The orientation of the pipelines relative to each other and the edge of the roof can be any and is determined by the structure of the building.

The figure schematically depicts one version of the system in which the pipelines oriented along the roof surface are located on the roof at an angle to each other.

The system comprises a housing 1, in which an exhaust fan 2 and a radiator 3 are installed, which are integrated in the pipes 5 of the heating system that are led into the attic 4. Holes are made in the housing 1, one of which has a pipe 6 connected to the exhaust channel 7 of the building, and the other has a pipe 8 that is led to the roof 9. A fan 2 is installed between the radiator 3 and the outlet end of the pipe 6.

The housing 1 is made with thermal insulation provided by its lining with insulating material, which can be

used various thermal insulation materials, such as polyurethane foam, polyethylene foam, etc.

The pipeline 8 brought to the roof 9 is connected by one or more pipelines 10 located on the roof surface 9 to the nozzles 11. To increase the pressure in the nozzles 11, the end of each pipeline 10 is provided with a plug 14.

For the convenience of laying the pipelines 10 on the surface of the roof 9, they are flexible, for example, from fabric airtight material, which also reduces the weight of the pipelines 10 and, therefore, the load on the roof 9.

The system operates as follows.

The air of the attic room 4 in the area of the radiator 3, the temperature of which is at least 30 ° C, is heated by the latter and is supplied by a fan 2 under a pressure of 12-15 kN / m2 through a pipe 8 through a pipe 10 to the roof 9. Heated air exiting through the nozzle 11 blows roof 9, causing melting snow and ice.

The use of air taken through the pipe 6 from the interior of the building through the ventilation channels 7 as a heat carrier allows air to be heated to higher temperatures without unnecessary energy consumption and to prevent ice formation on the roof 9. The thermal insulation coating of chamber 1 serves the same purposes.

Under the influence of heated air blown through the nozzle 11, the snow is blown off simultaneously with its melting, as well as the evaporation of melt water.

The system is applicable both for residential buildings with a sloping or flat roof, and for buildings with a hinged membrane roof. In the building, it is advisable to use as many systems as the number of pipes of the heating system and ventilation ducts brought to the attic. The performance of a roof heating system with an area of 10,000 m2 is ≈25000 m3 / h. The energy costs for the efficient operation of the system are determined only by the energy costs associated with the consumption of electricity by the fan. Small energy costs for ensuring the operation of the system allow the system to be used throughout the winter period.

The system does not require large material costs for its implementation and can be provided for in the construction of buildings, as well as for the modernization of the roofs of buildings in operation.

Claims (8)

1. A system for removing snow and ice from the roof of a building, comprising a pipeline leading to the roof, connected at one end to a fan, and a heater, characterized in that the heater is made in the form of a flowing radiator, the ends of which are built into the pipe of the heating system that is led into the attic, while the radiator is installed in the attic between the fan and the pipeline. 2. The system according to claim 1, characterized in that a pipe connected to the exhaust channel of the building is connected to the radiator. 3. The system according to claim 1, characterized in that the pipeline led to the roof is connected to at least one pipe oriented along the roof with at least one nozzle. 4. The system according to claim 3, characterized in that the pipeline oriented along the roof is located on the outer surface of the roof and / or near its inner surface. 5. The system according to claim 3, characterized in that at least one pipeline located on the roof is made with a blind end. 6. The system according to claim 3, characterized in that the pipeline oriented along the roof is flexible. 7. The system according to claim 2, characterized in that it comprises a housing in which a fan, a radiator and an outlet end of a pipe connected to the exhaust duct of the building are installed. 8. The system according to claim 7, characterized in that the inner surface of the housing is made with thermal insulation.