RU177939U1 - DEVICE FOR PREVENTING EDUCATION OF NALEDIA ON THE EXTENT OF ROOFS - Google Patents

Abstract

The proposed utility model relates to the field of construction, in particular to devices to prevent the formation of ice and icicles on the edge of the roofs when snow melts. Compared with the known devices, the proposed device is reliable in operation and provides quick removal of snow from the edge of the roofing, thereby preventing the formation of ice and icicles, in addition, the device is easy to replicate, has a low installation complexity, has high operational reliability, reduces energy costs During roof operation, the device is manufactured using hot melt glue by the method of thermal action on a film heating element with a positive coefficient of thermal resistance (TCR) of the order of + 40 С 101 / ° С, made on a flexible dielectric polyethylene terephthalate (lavsan) substrate by the method of screen printing in the form of parallel resistive tracks of a composite paste of a mixture of graphite, fine carbon black, a mixture of fine powder nickel-aluminum (Ni-53%, Al-47%) and ep EP oxyphenol varnish (PE-993). The resistive paths are supplied with power through conductive paths, which are also produced by screen printing with a conductive paste composition: a mixture of nickel-aluminum powder (Ni-53%, Al-47%) and EP epoxyphenol varnish (PE-993), to increase the degree of reliability, a strip of copper foil is laid parallel to the conductive paths. By thermal pressing, the heating element is covered with a metallized polyethylene terephthalate (lavsan) film, the upper metallized layer protects the heating element from external influences in the form of ultraviolet radiation and serves as a grounding contour. Food to the heating element is carried out mechanically by peeling off the protective film at the location of the current paths, which is subsequently sealed in accordance with the rules for the use of electrical installations (PUE).

Description

The proposed utility model relates to the field of construction, in particular to devices for preventing the formation of ice and icicles on the edge of the roofs when snow melts. The use of devices to remove or prevent the formation of frost and icicles is vital, since they are designed to increase the safety level of building operation, the movement of vehicles and pedestrians, in addition, the ice accumulated on the roof causes deformation and the gradual destruction of the roof.

A device for removing icicles, ice and snow from the edges of the roof of the building / RF Patent No. 2504627 E04D 13/076 2012 /, which contains a flexible elastic band protruding beyond the edge of the roof, made as part of a hollow cylinder, which is a nonlinear relay element with two steady states. The edges of the strip are attached to the edge of the roof and to the brackets mounted on the wall under the strip using elliptical guide slots with pins made in the strip. Permanent magnets are fixed under each other on the bottom surface of the strip and on the brackets, facing each other with the same poles with the possibility of adjusting the gap between them using a movable threaded sleeve fixed to the bracket, on the end of which a magnet is mounted.

A device for removing icicles from overhangs of the roof / RF Patent No. 2503785 E04D 13/076 2012 /, which includes a working body mounted on the wall using brackets with a drive mechanism and icicle cleavers. The working body is made in the form of arched staples suspended on a stretched string. The latter is equipped with a balancer in the form of a rod and a counterweight. Scalators are a rigid rod connecting the upper ends of the staples. The drive mechanism is made in the form of a trough-shaped tube cut off from above for accumulating melt water in it, attached to the bottom of the arcuate brackets directly under the edge of the overhang.

A device is known / RF Patent No. 2480563 E04D 13/076 2011 /, where the heating element is made in the form of an elastic steel wire, bent over a certain walking distance with the formation of narrow loops equipped with outward facing loops and pointed at the ends of the transverse pins. From below, on each of the loops, a sleeve made of an elastoplastic material of the type sotoplast, having a honeycomb volumetric structure with open outward cells, is tightly fitted and tightened. The technical result of the invention is to increase the operational reliability of the roof.

A device for protecting the roof against icing and icicles is also known / RF Patent No. 2463415 E04D 13/076 2010 /, which includes a coolant supply line forming a closed loop, an evaporator and a coolant, while the coolant supply line consists of a supply gas pipeline, a condensation gas pipeline condensate pipe. The connection of the evaporator with the gas pipe and the condensate pipe is made with the possibility of the coolant vaporized in the evaporator through the supply gas pipe to enter the condensation gas pipe, which is made with the possibility of heat exchange with the roof elements or elements of the drainage system in which the coolant is condensed, and can be passed through the condensate pipe in the liquid phase to the evaporator, evaporator placed in the heat flux. The device is hermetic and made with the possibility of installing devices or systems for monitoring the parameters of the coolant.

The closest analogue is a device / Patent RF 107804 E04D 13/076, 2011 / to prevent the formation of ice and icicles on the eaves overhang of the roof, containing a heater located along the lower part of the roof, characterized in that the heater uses a film electric heater, which is located on the inside side of the eaves overhang of the roof. The device additionally contains an insulating coating located on the outside of the film electric heater, the film heaters are equipped with an earthing circuit and protective shutdown devices, the adjustment of the range of the system is carried out both automatically and manually. The film electric heater is placed at a distance of 50 mm from the edge of the roof.

The disadvantages of the known devices is that they are difficult to implement, so they are not widely used. Known devices are laborious, difficult to manufacture and install, have low operational reliability, energy intensive, in some cases require specialized maintenance personnel. In addition, devices to remove ice are struggling with the consequence, not the cause, so they do not solve the problem of improving the operational reliability of the roof.

The closest analogue solves some of these problems, but it has a number of significant drawbacks. The installation of the proposed device can only be installed when installing the roofing or replacing the old roofing, but it is necessary to make a passage through the rafters or fit it between the roofing and the crate, the initial crate is installed exactly at the place where it is recommended to install the film heating element. When installing on an operated building, it is necessary to dismantle the drainage system, remove the binder and free the edge of the roof to install heating elements, and if the building is above 2 floors, then specialized equipment and specially trained personnel will be required. Installing localized heating in a non-ventilated space with sharp temperature drops causes condensation to form, respectively, at temperatures below -5 ° C, when, as a rule, anti-icing systems do not work, the condensate will freeze and destroy the roof. In this case, the use of a residual current circuit breaker (RCD) is relevant, since the system will not be able to work until it dries. The structural elements of the roof and the roofing have their own heat capacity, installing a heating element under the roof, using the described methods it is impossible to ensure a tight fit to the roof, therefore, the whole structure will gradually warm up, including the roofing and the snow that will be on it, which will lead to high energy costs.

The objective of the proposed utility model is to create an easily replicable device with low labor input for manufacturing and installation, with high operational reliability, as well as reducing energy consumption during roofing and increasing the operational reliability of the roof.

This object is achieved in that in the device for preventing the formation of ice on the edge of the roofs containing a film heater located along the lower part of the roof, consisting of polyethylene terephthalate (lavsan) film, onto which parallel resistive tracks made of composite paste are applied by mesh screen printing, consisting of from a mixture of graphite, finely divided carbon black, a mixture of finely divided nickel-aluminum powder (Ni-53%, Al-47%) and EP epoxyphenolic varnish (PE-993), resistive paths are connected Powered via conductive paths deposited by the method of mesh-screen printing, with a strip of copper foil laid parallel to them, by the method of thermal pressing, the heating element is coated with polyethylene terephthalate (lavsan) film, which has a metal coating with hot-melt adhesive.

Conducting paths are made of paste prepared in the ratio: 75-80 wt. % - a mixture of finely divided nickel-aluminum powder (Ni-53%, Al-47%) and 20-25 wt. % - EP epoxyphenol varnish (PE-993)

The device according to claim 1, characterized in that for fixing the film heater, a massive plate is laid on top of it, in which heating elements are installed, heating it to the melting temperature of the hot-melt adhesive, the temperature of which is monitored by a temperature sensor.

A diagram of the device is shown in FIG. one.

The heating element 1 is made on the basis of a polyethylene terephthalate (lavsan) film, which has thermoplastic properties and can be used in the temperature range from -65 ° C to + 155 ° C, is resistant to aggressive chemical environments, to the effects of oils, sunlight, ultraviolet, has high dielectric properties. The heating element consists of a dielectric polyethylene terephthalate (lavsan) substrate 2, onto which parallel resistive paths 3 of a composite paste consisting of a mixture of graphite, fine carbon black, a mixture of fine powder nickel-aluminum (Ni-53%, Al -47%) and EP epoxyphenolic varnish (PE-993). The resistive composition is prepared in the ratio: 15-16 wt. % - graphite, 19-23 wt. % - carbon, 62-65 wt. % - nickel-aluminum powder. The resulting composition is mixed with epoxyphenol varnish in the ratio: 50-70 wt. % - composition, 30-50 wt. % - varnish.

The resistive paths are supplied with power through the conductive paths 4, which are applied by the method of mesh-screen printing. Conductor paste is prepared in the ratio: 75-80 wt. % - a mixture of finely divided nickel-aluminum powder (Ni- 53%, Al-47%) and 20-25 wt. % - EP epoxyphenol varnish (PE-993), to increase the degree of reliability, a strip of copper foil is laid parallel to the conductive paths 5. By means of thermal pressing, the heating element is covered with polyethylene terephthalate (lavsan) film 6, which has a metal coating 7, the upper metallized layer protects the heating element from external influences in the form of ultraviolet and serves as a grounding circuit. Hot melt adhesive is applied to the dielectric polyethylene terephthalate (lavsan) substrate 8. Power is supplied to the heating element mechanically by peeling off the protective film at the location of the current paths, which is subsequently sealed in accordance with the rules of electrical installation (PUE).

The mounting scheme of the proposed device is shown in FIG. 2. The heating element 1 is laid in places of possible formation of ice and icicles, along the edge of the roof covering 9 roofs, awnings, peaks over the film heating element, a massive plate is applied. In the case when the edge of the roofing has a smooth surface, a plate with a smooth surface of 10 a is laid, in the case where the edge of the roofing has a relief surface, for example, a profile sheet, a plate is laid that completely repeats the surface of the coating 10 b. Heating elements 11 are installed in the stove, which heat it up to the melting temperature of the hot melt adhesive, the temperature of the stove is controlled by the temperature sensor 12.

The device to prevent the formation of ice on the edge of the roof is designed for roofs that have a slope of more than 15 °.

The device operates as follows:

The device is connected to the control panel in accordance with the rules of the electrical installation (PUE) and can operate both in automatic and manual mode. When installing the device on the visors of balconies, entrance doors, awnings, the automatic control device is not cost-effective, manual control is sufficient for reliable operation and cost reduction of the product. The installation is turned on when the external temperature rises and approaches to -5 ° C, it can be turned on at lower temperatures when snow accumulates at the edge of the roofing. The heating element has a positive coefficient of thermal resistance (TCS) of the order of + 40 ∙ 10 ^-4 1 / ° С, so when voltage is applied, a large amount of energy is released at the initial moment, which does not melt a lot of snow in the lower part, then when heated of the heater and the roof, the power gradually decreases to a level that does not freeze the water layer that forms between the snow cover and the heating element. Under the influence of gravity, the snow cover “moves off” from the roofing, after which the heating element works until the melt water evaporates, after which the device stops working.

Compared with the known ones, the proposed device is reliable in operation and provides quick removal of snow cover from the edge of the roofing, thereby preventing the formation of ice and icicles, in addition, the device is easily replicated, has low installation complexity, has high operational reliability, and reduces energy costs when operating the roof.

Claims (3)

1. A device for preventing the formation of ice on the edge of the roofs, comprising a film heater located along the lower part of the roof, characterized in that the film heater consists of a polyethylene terephthalate (dacron) film, onto which parallel resistive tracks of composite paste are applied by mesh screen printing, consisting of a mixture of graphite, finely divided carbon black, a mixture of finely dispersed nickel-aluminum powder (Ni-53%, Al-47%) and EP epoxyphenol varnish (PE-993), resistive bonds They are powered by wire paths deposited by the method of mesh-screen printing, with a strip of copper foil laid parallel to them, by the method of thermal pressing, the heating element is coated with a polyethylene terephthalate (dacron) film, which has a metal coating with hot-melt adhesive. 2. The device according to p. 1, characterized in that the conductive paths are made of paste, prepared in the ratio: 75-80 wt. % - a mixture of finely divided nickel-aluminum powder (Ni-53%, Al-47%) and 20-25 wt. % - epoxyphenolic varnish EP (PE-993). 3. The device according to claim 1, characterized in that for fixing the film heater, a massive plate is laid on top of it, in which heating elements are installed, heating it to the melting temperature of the hot-melt adhesive, the temperature of which is monitored by a temperature sensor.

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