RU2340746C2 - Anti-icing device used for roofs - Google Patents

Abstract

FIELD: construction industry.

SUBSTANCE: invention refers to construction industry, and namely to devices preventing ice formation on roof verges. Device consists of tubular heating element with exhaust openings, which is attached in contact with roof verge and is located in a roof section or along roof perimeter, thus forming closed circuit. Tubular heating element is connected with transport air piping, and at that air intaking ends of transport air piping are located in air ducts of the building below exhaust openings provided at the bottom of tubular heating element at its ends when arranging heating element on some part of roof, or in the form of longitudinal cut-outs distributed along the length of tubular heating element during its arrangement along roof perimeter.

EFFECT: reliable continuous operation of anti-icing device in autonomous mode without providing any maintenance.

1 dwg

Description

The invention relates to the field of construction of devices for preventing the formation of frost on the edges of the roofs.

A device for heating roof overhangs, containing a circuit of pipelines with a coolant, a heating medium coolant connected to a central heating system (AS USSR No. 30417, KL. 37 s, 11, publ. 05.31.1933).

The disadvantage of this device is the significant cost of heating the coolant - water from the central heating system - to melt ice on the eaves of the roof.

A device for removing icicles from roofs is known, comprising a loop installed along the cornices from pipelines with a coolant inside them in the form of an electric heater from an electric power source (Japanese patent No. 4-2150, MKI: E04D 13/00, published on January 16, 1992).

The disadvantages of this device are the lack of reliability of the trouble-free functioning of the electric heating element and the significant cost of electricity consumed.

A device for melting snow on the roof of the house is known, comprising a circuit of pipelines with at least one inlet and one outlet pipelines with a coolant, a heating medium heating device in the form of a boiler connected to a heating source, an expansion tank associated with the circuit, a circulation pump, a control device (Japan patent No. 2840576 B2 9021215 A, MKI: E04D 13/00, publ. 12.24.98).

The disadvantage of this technical solution is the use of water coolant from the boiler, which is susceptible to freezing both at low atmospheric temperatures and when the heating system of the boiler fails, which will require additional costs for maintaining the circulating coolant during operation of the device. In addition, the presence of expensive electrical equipment as part of the control device, which also includes sensors requiring heating elements, such as a fan, electric lamps, etc., increases the cost of the device.

A device for melting icing of roofs is known, comprising a circuit of pipelines with at least one inlet and one outlet pipelines with a heat carrier, a heating device for a heat carrier connected to a heating source, an expansion tank associated with the circuit, a circulation pump, a control device, wherein the circuit is made closed and with the joint section of the outlet and inlet pipelines interacting with the heating device, the heating source of which is made in the form of a heating system A circulation pump is connected to a circuit and to a control sensor, and frost-resistant material is used as a heat carrier. In addition, the heating device can be made in the form of a boiler with a coil connected to the central heating system, the control device can be made in the form of a temperature sensor, and antifreeze can be used as frost-resistant material (RF PM No. 28882 7 Е04Д 13 / 00, 13/076 publ. 04/20/2003).

The disadvantages of this device are the relative complexity and multi-link structure, considerable costs for the manufacture, installation and operation.

A device for removing snow and ice from the eaves of the roof, containing mounted on the outer edge of the roof closed in cross section, made in the form of a sheet of soft metal with a heater located on it, covered with an insulating layer, the heater is equipped with down conductors for connection to a power source (RF P.M. No. 23634, M. C. E04D 13/00, publ. 2002).

The disadvantages of this device are the increased danger due to the use of an electric power source, low operational reliability and significant operating costs when melting ice and snow.

An analogue of the claimed technical solution is a device for removing snow and ice from the eaves of the roof, containing a working heating element fixed to the outer edge of the roof of the building, connected to a heat energy source, and fasteners, characterized in that it contains a heat generator and a coolant transportation pipeline, this working heating element is made in the form of a pipe mounted on the edge of the eaves overhang of the roof by means of brackets providing thermal contact and the outer surface of the heating element with the lower surface of the eaves overhang of the roof, while the working heating element is connected through the pipeline transporting the coolant to the heat generator. This well-known solution has several options:

item 2, the heat generator is installed in the basement of the building, and the pipeline for transporting the coolant is laid from the heat generator to the working heating element inside the building.

Clause 3, the heat generator is installed outside the building, and the pipeline for transporting the coolant is laid from the heat generator to the working heating element on the outside of the building with thermal insulation.

Claim 4, the heat generator comprises a central heating radiator located in an airtight heat-insulated container, in the lower part of which an air intake is installed, and in the upper part there is an exhaust pipe connected to the coolant transportation pipeline.

p. 5, the heat generator is installed in the attic of the building and contains an electric heating element and a fan associated with the heat transfer pipeline.

p. 6, the heat generator is installed on the car and is connected to the pipeline for transporting the coolant through a flexible sleeve.

Claim 7; The device according to claim 1, characterized in that it comprises exhaust pipes mounted on the roof cornice along the working heating element.

The disadvantages of this device are the need for the manufacture of heat generators and associated equipment and equipment, as well as the economic costs of heating the coolant and maintaining the device. In addition, the presence in the design of exhaust pipes in the form of pipe sections connected with a heating element (2, drawing) helps to create an emergency situation when snow pipes are clogged with snow despite snowstorms, despite the presence of protective covers over them that protect the pipes from getting there is snow only in calm weather (there are frequent cases of snow clogging with strong snow blizzards of exhaust pipes of similar structures from basements and cellars). Snow in the exhaust pipes during thaw and subsequent lowering of the temperature can turn into ice plugs, after which all the options described in the prototype will be inoperative until the plugs are removed.

The purpose of the proposed technical solution is to prevent the formation of icing (icicles) at the edges of the roofs by using permanent devices without artificial heat generators.

The technical result is achieved in that the proposed anti-icing device for roofs, comprising a conductive heating element fixed to the roof edge and connected to a heat source by means of a transport duct, is characterized in that the transport duct is in communication with the ventilation duct of the building, and the heating element is made with exhaust holes in its bottom, ensuring constant flow of coolant in the downward direction.

The drawing shows a layout of the elements of the device and its functioning.

The essence of the proposed device is as follows.

In contact with the edge 1 of the roof 2, a heating element 3 is laid and fixed, for example, by conventional brackets in the form of, for example, low-pressure metal pipes in the desired section or along the perimeter of the roof, with the formation of a closed loop. In the bottom of the heating element 3 at its ends or dispersed along its length in the case of the formation of a closed loop, exhaust openings 4 are made in the form of, for example, longitudinal cuts for 1/3 ⌀ pipes. To the heating element 3 are connected transport ducts 5 in communication with the ventilation channels 6 of the building. Conveyor ducts can be made in the form of ordinary rubber or plastic non-pressure flexible hoses (for central water heating of a building) or in the form of metal heat-resistant pipes (for stove heating), passed into ventilation ducts 6, for example, from the attic, through special openings in their walls . The lower intake ends (inlets) of the transport ducts are located in the building's ventilation ducts below the level of the exhaust openings 4 (Δh) with a natural upward pull of warm air through the transport duct 5 and the heating element 3.

The proposed device operates as follows. In periods when the outside temperature is lower than the temperature of the warm air in the ventilation duct of the building, warm air (shown by arrows in the drawing) from the ventilation duct 6 along with the main flow outward is sucked into the transport duct 5 through its intake end (suction) and enters heating element 3, from which through exhaust openings 4 flows out. The traction force of warm air and its amount in the heating element is determined by the cross-sectional area of the transport duct 5, the heating element 3 and the exhaust hole 4, as well as the level difference (Δh) of the suction of the transport air duct 5 and the exhaust hole 4.

The proposed device is effective for the entire temperature range of ice formation, from almost the plus temperature to -10 ° C: melt water flowing down the roof 2, through its edge 1 will certainly fall on the heating element 3 in contact with it, through which it flows to the ground. When cooling, the melting of snow slows down and a gradual icing of the roof begins. But the water that continues to flow to the edge 1 of roof 2 does not freeze, because heated by a warm heating element 3 even after the cessation of snowmelt and the beginning of ice formation, i.e. the place where the icicles grow from remains warm during the period of their potential formation and growth. This ensures that frost does not form on the edges of the roofs.

The proposed device includes the technical options indicated in the analogues in the form of the presence and location of the heating element, the transport duct, and the use of the well-known convection phenomenon. However, some differences suggest it is more effective than the known ones:

1. Known devices are intended for melting snow and already formed ice (icicles);

- the proposed device prevents the formation of frost.

2. Known devices include the use of artificial sources of thermal energy (heat generators) with the inevitable costs of their manufacture, installation and operation;

- the proposed device uses a free coolant, and the design is as simple as possible (transport duct + heating element), the device can operate in trouble-free autonomous mode for decades, without maintenance costs.

3. Known devices operate in a cyclic (periodic) mode of operation, involving starts and stops and the involvement of staff;

- the proposed device is operated continuously without maintenance.

4. During the operation of known devices, additional costs are inevitable for observing safety measures against icing (icicles) falling from the roofs;

- during the operation of the proposed device, additional safety measures are not needed - melt water falls from the roofs, and not ice blocks.

5. In the known device (prototype), the coolant from the heating element expires through the exhaust pipes in an upward flow, which does not exclude emergency situations when the pipes are clogged with snow with strong snowstorms;

- in the proposed embodiment, the outflow of the coolant from the heating element is carried out through the holes in its bottom part in a downward constant flow, which eliminates the ingress of snow into the heating element.

The proposed device can be used both on buildings under construction and in operation, its use will eliminate numerous injuries from falling from ice roofs.

Claims (1)

An anti-icing device for roofs, comprising a heating tubular element with exhaust openings fixed at the contact with the edge of the roof and located on its section or along its perimeter to form a closed loop, connected to the transport ducts, characterized in that the intake ends of the transport ducts are placed in the building ventilation ducts below the exhaust openings made in the bottom of the heating tubular element at its ends when the heating element is on Asti roof or dispersed in the form of longitudinal notches along the length of the tubular heating element at its location on the roof perimeter.