RU131768U1 - PNEUMATIC DECOMPOSITION SYSTEM FOR THE ELIMINATION OF Icicles on the roofs of buildings - Google Patents

Abstract

Pneumatic de-icing system for the elimination of icicles and ice on the roofs of buildings, containing a sealed tread made of elastomeric or rubber-reinforced material with water-repellent properties, for example, silicone or fluorosilicon rubber with the ability to connect to a compressed air source (compressor), characterized in that the tread is made of flat folded in half in the longitudinal direction of the rolled sheet with an inlet δ = 10 ... 30 cm of one of the sides, which freely fits the volume from all sides a large coarse mesh, for example, of a rectangular shape, covering the entire inner area of the tread, through which a tube with fittings at the ends is passed and which is attached to the edge of the coarse mesh on the inlet side, the part of the tube in the tread being perforated with holes or holes in the form of nozzles and the output of the compressed air source (compressor), through the first output of a splitter (tee) connected to its output, and the hose are connected to the inlet fitting of the tube, the outlet fitting which is closed by a plug Coy, the second output of the splitter (tee) is connected to the input of a normally open electric fan, the winding of which and the compressor motor winding through a two-pole switch are connected in parallel to a low-voltage, for example 12 V, power supply and to a socket for connecting to an autonomous low-voltage portable power supply system.

Description

The utility model relates to the field of construction and housing and communal services and is intended to eliminate icicles and ice on the roofs of buildings, which pose a serious threat to passers-by and vehicles in places of their possible fall.

The problem of eliminating icicles and ice sharply arose in St. Petersburg in the winter of 2010, when as a result of a multi-snowy winter, roofs of 1,300 buildings leaked in only one Central region, 5,000 apartments were damaged. As a result, more than 0.5 billion rubles were allocated for the repair of all damaged roofs from the city budget. In addition, more than 260 people were affected by the fall of icicles in the city (http: /www.kadis.ru/texts/index.phtml.? Id = 8876). As a result, the Government of St. Petersburg issued a decree dated 10.08.2010 No. 1061 “On the Prize of the Government of St. Petersburg for the best innovative project aimed at applying new technologies for snow removal and removal of ice from the roofs of buildings in St. Petersburg ". However, due to the complexity of the task, this competition did not lead to any significant results. The task as before remains relevant and requires its solution with the involvement of specialists of various specialties.

So, the most effective way to deal with icicles at the design and construction stages of buildings. As you know, the main reason for the formation of icicles and ice is the warm pitched roof, heated from below by the heat coming from the attic. To reduce the influx of this heat, “purges” are made - special open windows on the roofs. Academy of Public Utilities named after KD Panfilova offers for this purpose to apply a heat-insulating coating, for example, with polyurethane, from the inside of the attic to the roof lathing and roofing iron, which will reduce their heating. According to the results of the above-mentioned competition for the Prize of the Government of St. Petersburg for the best innovative project, the winner was the project involving the application of ecowool made from recycled materials — old newspapers and linen — to the roof crate and roofing (the Komendantsky airdrome regional newspaper No. 27 (218) for December 2010 of the year). There were also suggestions for warming attic floors with aerated concrete slabs.

All these decisions are inherently palliative and cannot be fully implemented in the conditions of the historical city fund, whose buildings with wooden floors and with pitched roofs have a lot of wear. In addition, there is no guarantee regarding the durability of the coatings applied to the roof lathing and roofing iron from the inside of the attic, and old wooden coatings may not support the weight of heat-insulating slabs made of aerated concrete slabs.

Therefore, the development of new devices intended for the direct elimination of icicles and ice formed on the pitched roofs of buildings is very relevant. There are several types of devices for combating icing of protected objects: thermal, mechanical, pneumatic and hydrophobic. Thus, devices that implement the thermal protection method include sleeves laid along the edge of the roof, along which hot water or hot air is supplied (RF patents No. 2333326, IPC E04D 13/076 of 05/27/2006; No. 2441122, IPC E04D 13/076 of 10.10 .2011; IPC E04D 13/080 of 06/20/2007), or electric heating cables or elements (RF patents No. 2310727, IPC E04D 13/076 of 11/10/2007, No. 2371339 IPC E04D 13/076 of 2/27/2009, RF patent No. 2161680, IPC E04D 13/064 dated 10.01.2001).

Devices that implement a mechanical method of protection against icicles and icing contain mechanical, electromechanical piezoelectric elements to create pulsed deformations or vibrations in the roof material in order to prevent the formation and destruction of icicles and icings already formed on the edges of the roof and on the roof itself (RF patents No. 2327829, IPC E01H 5/12 dated 10/27/2007, No. 2439261, IPC U05V 13/076 dated 11/20/2011). The main disadvantage of these devices is the negative impact on the roofing material.

Devices including hydrophobic roof coatings (for example, RF patent No. 2291261 IPC E04D 13/076 of 08/17/2005) is not sufficiently reliable and, first of all, due to the low durability of these coatings.

Devices that implement the pneumatic method of protecting objects from icing are widely used in aviation (US patents No. 4516745, IPC И64В 15.18 dated 05/14/1985, No. 4358075, IPC И64В 15.02 dated 09/09/1982). Various designs of pneumatic de-icing devices used in aviation are described in the book: Functional Systems of Aerospace Engineering / A.V. Betin, N.V. Bondareva, V.N. Kobrin, S.A. Lobov, N.V. Nechiporuk. - Training Allowance. - Kharkov: Nat. Aerospace University "Kharkov Aviation Institute", 2005. - 112 p.)

However, all these technical solutions are fully adapted to this subject area (aviation) and are difficult to implement to solve the problem of creating anti-icing devices for removing icicles and ice on the roofs of buildings. At the same time, it should be noted that pneumatic de-icing systems are capable of creating very significant efforts to destroy icicles and ice, which makes them very promising for protecting buildings from icicles and ice in severe climatic conditions. This circumstance has been confirmed in the devices for unloading bulk frozen cargo from railway platforms, cars and trailers containing a flexible shell placed under the load, and into which compressed air is supplied during unloading, under the influence of which the shell inflates and creates a force under which the load is lifted and dropped from the vehicle (see AS No. 115804, IPC B60P 1/00 dated 05/30/85, AS No. 1161420, IPC B60H 1/00 dated 06/15/85).

In view of the above, of all known methods and devices for controlling icicles and icing of roofs of buildings, it is advisable to use devices that implement the pneumatic method of controlling icicles and icing as the most effective and adapted way to deal with icicles in harsh climates.

The closest analogue to the claimed utility model is a device for combating icicles and icing proposed by the housing committee of the administration of St. Petersburg. This device includes a "polymer gut", laid along the perimeter of the house, and a source of compressed air. When the ice begins to appear, the hollow polymer hose is pumped up with air, and the ice outgrowth flies off from the roof in a safe volume. This device is described by the information agency ROSBALT, Russia, St. Petersburg, document www.rosbalt.ru/2010/08/10/761088/html, date 2010-08-10 18: 26: 00 + 04.

The disadvantage of this device is that with significant cooling and temperature differences in a number of sections of the "polymer gut", which will be called the protector in the future, it is possible to freeze its individual sections, which can block the flow of compressed air to a number of areas of the "gut" (tread) . All this reduces the efficiency of the device and its reliability. On the other hand, the natural desire to increase the patency of a frozen tread by supplying it with increased air pressure increases the likelihood of a tear rupture, which also reduces its reliability. In addition, laying the “gut” protector over the entire facade of the building, its protrusions and bends can lead to a narrowing of the section (“gut”) (tread), and in some cases to its overlap and accelerated freezing at low temperatures and their large differences.

Freezing of the tread shell leads to the fact that the shell cannot completely expand when compressed air is supplied to it, as a result of which the ice and icicles formed on this part of the tread, which froze and did not expand, will not be destroyed, which reduces the reliability of the device.

On the other hand, the desire to nevertheless eliminate the ice and icicles that remained intact on the surface of the frozen part of the tread by re-inflating the tread shell or increasing the pressure of this boost will increase the load cycles of the tread shell and increase the load with each cycle of loading of the tread shell and, therefore, will also reduce the reliability of the device.

Facades and roof edges, especially in the historical part of the city, have a complex configuration, which makes it difficult to use various anti-icing systems, especially pneumatic ones, due to the numerous bends and the narrowings caused by them. Significant difficulties arise when laying long pneumocommunications, placing and installing sources of compressed gas and their controls. All this significantly narrows the scope of existing applied pneumatic de-icing systems for the elimination of icicles and ice on the roofs of buildings.

Thus, the technical task of the claimed utility model is to increase the reliability of the device and expand the scope of its application.

So, increasing the reliability of the claimed device is ensured by introducing a large coarse mesh into its composition, as well as by making a tread sheath of elastomeric material folded in half in the longitudinal direction with the inlet of one of the sides freely fitting the flexible coarse mesh located inside the shell. Such a design of the tread shell eliminates its pre-tension, leading to pre-loading of the shell. The voluminous coarse mesh inside the tread does not allow the walls of the tread shell to stick together due to its freezing and provides free access to the air supplied from the compressor to all the inner parts of the shell. The preliminary tension of the casing in the initial state (until it is pressurized) is excluded by its communication with the atmosphere using a normal open electric fan.

The tread shell is made of hydrophobic (water-repellent) elastomeric material, for example, silicone rubber, fluorosilicon rubber, polyethylene, etc., for strength reinforced with threads. This contributes to the free flow of water from the roof, not lingering on the shell, which further increases the efficiency of the inventive device.

The reliability of the device is ensured by the location of the tread so that melt water flowing from the roof falls on the tread located below and freezes, forming icicles and ice on its surface, and not on the edge of the roof, which is achieved by attaching the tread by letting its shell to the underlying elements roofing.

In addition, the use of tubes perforated with holes or holes in the form of nozzles, through which compressed air is supplied to pressurize the tread, ensures uniform filling, eliminates dynamic loads, which increases the reliability of the claimed device.

A protector with a tube and a large coarse mesh can be considered as a separate elementary module, which allows you to create modular designs when the outlet fitting with the plug removed is connected to the inlet fitting of another tube passing through its protector, etc. The presence of perforated tubes connected in this way allows you to create modular designs of the most diverse configurations, which expands the scope of the device.

With a large number of modules, they can be connected to each other using flexible hoses, various adapters, etc., forming a single multi-link flexible tube, individual links (modules) of which can bend around and repeat the most complex contours of building facades and edges of gable roofs. In this case, the source of compressed gas (compressor) through the splitter can be connected to the pipe formed in this way in two ways. With a small number of modules, the source of compressed gas (compressor) is connected through a splitter (tee) to the input of the tube of the first module, and the outlet fitting of the last module is closed by a plug. In this case, the filling of the protectors of all modules is carried out by the compressor of the first module. With a large number of modules, the performance of one compressor may not be sufficient, therefore, the compressor of the last module can be connected to the output fitting of the last module of the multi-link tube, which in this case is fully equipped and turns on (off) synchronously with the compressor and electric fan of the first module. In this case, the filling of the protectors is carried out by two compressors, which speeds up the process of application of the device. It should also be noted that the protruding parts of the tubes coming out of their protectors can be used for attaching multi-link modules to building structural elements.

The inventive device is designed to operate in hazardous conditions (precipitation, large temperature differences, high humidity, etc.), which necessitates the use of low-voltage power sources, such as 12 V, to power the windings of the compressor motor and electric fan.

Thus, a single technical result achieved in the implementation of the claimed invention is to increase the reliability of the device and expand its scope.

In the drawing of Fig. 1, the claimed device is shown with an angular cutaway and in a section, in Fig. 2 - icicles and ice on the tread, in Fig. 3 - the process of their destruction, in Fig. 4 - a wiring diagram of the device on the protected building.

Presented in figure 1, the claimed device includes a tread 1, made in the form of a freely folded in the longitudinal direction of the roll of cloth from an elastomeric or unreinforced material with an inlet 2 of size δ = 10 ... 30 cm on one side. All edges of the rolled sheet forming the tread are hermetically sealed. A tube 4 is inserted through the tread shell through the sealed entries - 3, a part of which inside the tread is perforated with holes 5 or nozzles. Inside the tread, a coarse coarse mesh grid 6 is attached to the tube along its entire length to the inlet side. At the ends of the tube 4 exiting the tread, an inlet 7 and an outlet 8 are installed. The compressor 9 through the first output I of the coupler 10 (tee) connected to its output is connected via the hose 11 to the input fitting 7 of the tube 4, and the second output II of the coupler (tee) 10 is connected to the input of the normally open electric valve 12. The second (output) fitting 8 of the tube 4 is closed by a plug 13. The compressor motor 9 and the motor winding 13 are connected via a bipolar switch 14 to a low-voltage voltage source 15, for example 12 V, made either in a stationary or portable version. In the latter case, the compressor motor 9 and the electric winding of the electric fan 12 are connected in parallel to the socket 16, which includes the specified low-voltage voltage source.

The claimed device on the protected object is located as follows. So, in order to ensure the reliability of the device and, first of all, its component such as retention, the compressor 9 with the splitter 10 and the electric fan 12 are not located in the open air, where they can be exposed to various atmospheric influences, but in the attic or under the roof slope in the immediate vicinity of protected section of the roof near the installation site of the tread 1. The mount of the tread 1 on the roof of the building using the inlet 2 of the tread 1 is shown in figure 2. For this purpose, a low-voltage source of 12 V.

Device controls: socket 16, two-pole switch 14, through a four-wire cable is displayed on the control panel located in the technical or office premises of buildings and structures or in the concierge's room. The socket 15 for autonomous power supply of the system can be displayed and fixed on the outer surface of the wall of the building at a height convenient for connecting an autonomous power source and work with it.

The wiring diagram of the location of the claimed device on the protected building is shown in figure 4 in the notation adopted in figure 1.

The device operates as follows. In the initial state, the switch 14 is open, and an independent power source is not included in the socket 16. In this case, the device is in a de-energized state, and normally open in this state, the electric fan 12 communicates the tread cavity 1 with the atmosphere.

When a protector 1, made in the initial state and freely enclosing a flexible coarse mesh 6, is made on a completed protector 1, as shown in FIG. 1, FIG. 2, and FIG. 3, a kind of build-up of ice and icicles forms, an operator or a housing and communal service worker sets a switch 14 to the “on” position or connects the portable low-voltage source to the outlet 16. In this case, the voltage is supplied to the winding of the electric fan 12, which, when closed, closes its bore, forming together with the splitter (tee) 10, hose 11, w Utsera 7, the tube 5 and the interior of the closed volume of the tread 1. At the same time, voltage is supplied to the compressor motor 9, which starts to work and fill this volume with compressed air. Due to the presence of perforated holes or nozzles 5 in the tube 4 and the presence of a volumetric wire mesh 6 placed inside the tread 1, freezing of individual sections of the tread shell 1 is eliminated and compressed air exerts a uniformly increasing pressure on all the inner sections of the tread shell 1 when it is filled. When this pressure inside the tread 1 shell expanding under its influence exceeds the strength of the ice build-up (icicle), the latter collapses under the influence of normal and tangential stresses and breaking stresses, as shown in Fig. 3. When expanded, changed its original shape, swollen tread 1, the flexible volumetric mesh mesh 6, attached to the tube 4, is also deformed (see figure 3). Chunks of ice, broken off from a tread so deformed in a similar way, 1 from the icicles and ice that formed on it fall down to the house area, which is fenced off and protected during the elimination of icicles and ice, which ensures the safety of cleaning roofs of buildings from icicles.

After the icicles and ice are destroyed on the tread 1, the housing and communal services employee switches the switch 14 to the off position and / or de-energizes the socket 16. As a result, the compressor 9 stops functioning and the air supply to the tread 1, and the winding of the electric fan 12 is de-energized, as a result of which the bore opens again, communicating the tread cavity with the atmosphere. The previously stretched shell of the tread 1 under the action of elastic forces that had previously arisen in the material stretched as a result of the pressurization of the shell of the tread 1, is again pulled together and occupies the initial position shown in Fig. 1 (see section AA). after which the device is ready for use again.

With repeated and all possible subsequent attempts at destruction remaining or newly formed on the tread 1 of ice and icicles, the entire described above, the cycle of the device is repeated again.

The device described above can be considered as a separate stand-alone module. So, depending on the size and configuration of the buildings and roofs to be protected, the second protector is connected to the outlet fitting 8 of the tube 4 instead of the plug 13 using various adapters or flexible hoses, and the third one, etc. In this case, the modules assembled into a single system can freely repeat the configuration of the facades, the edges of the roofs and their protruding elements. Thereby expanding the capabilities of the device, and facilitating the removal of icicles and ice from the protruding elements of roofs and buildings, especially in the historical part of the city.

The technical effect obtained by using the claimed utility model for removing icicles on the roofs of buildings is to increase reliability and expand the scope of its application.

Thus, thanks to a new set of essential features, the task is solved and the above technical result is achieved.

Claims (1)

Pneumatic de-icing system for the elimination of icicles and ice on the roofs of buildings, containing a sealed tread made of elastomeric or rubber-reinforced material with water-repellent properties, for example, silicone or fluorosilicon rubber with the ability to connect to a compressed air source (compressor), characterized in that the tread is made of flat folded in half in the longitudinal direction of the rolled sheet with an inlet δ = 10 ... 30 cm of one of the sides, which freely fits the volume from all sides a large coarse mesh, for example, of a rectangular shape, covering the entire inner area of the tread, through which a tube with fittings at the ends is passed and which is attached to the edge of the coarse mesh on the inlet side, the part of the tube in the tread being perforated with holes or holes in the form of nozzles and the output of the compressed air source (compressor), through the first output of a splitter (tee) connected to its output, and the hose are connected to the inlet fitting of the tube, the outlet fitting which is closed by a plug Coy, the second output of the splitter (tee) is connected to the input of a normally open electric fan, the winding of which and the compressor motor winding through a two-pole switch are connected in parallel to a low-voltage, for example 12 V, power supply and to a socket for connecting to an autonomous low-voltage portable power supply system.

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