RU2658712C2 - Method of protection of drainage roof element surface of building roof against icing - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to the field of construction, in particular to methods of protecting the roof drainage elements against icing. Method includes an artificial increase in the speed of movement of melt water along inclined and vertical drainage elements of the roof of the building. To increase the speed of movement of melt water along the drainage elements of the roof, but all the perimeter of the building, under the edge of the roof, thin plates are placed in the immediate vicinity of the melting water flowing from it, facing the edge of the edge of the roof and the inner part of the drainage channels, made of sylvinite.

EFFECT: technical result of invention consists in improvement of roof load-carrying capacity.

1 cl, 1 dwg

Description

The invention relates to the field of construction, in particular to methods for protecting roof drainage elements from icing, and can be used in the household and industrial sphere, as well as in the operation of buildings and structures.

A known method of preventing the formation of icicles on the roof of the building, including attached along the edge of the roof in its area or around the perimeter with the formation of a closed loop heating element connected to the terminals for connecting an electric current source, made in the form of a metal conductor bent through a certain walking distance with the formation of hanging loops, a metal conductor is zigzag from alternately soldered segments of dissimilar conductors or semiconductors, forming a ring-shaped thermopile, the internal junctions of the thermopile being placed on the roof under snow, and the external ones outside the roof at its edge, and a millivoltmeter is connected to a pre-calibrated thermopile to measure the thermoelectromotive force, and after registering it, the positive temperature of the atmospheric air passes through zero to negative in this thermopile pass unidirectional electric current from the current source in the direction that provides heating of the external junctions and is cooled Internal junctions of the thermopile e [1].

The disadvantages of this method include high energy costs due to the low efficiency of the thermal battery.

There is also a method of protecting the surface of the drainage elements of the roof of the roof of the material object from icing, including the artificial increase in the speed of rolling melt water from the surface of the drainage elements of the roof, due to the fact that the surface of the drainage elements of the roof of the roof of the material object is applied a hydrophobic anti-wettable coating with a contact angle of more than 120 °, at the beginning of the vertical part of the drainpipe, a water-deflecting ring is placed, while the coating is applied to the surface of the receiving funnel, the inclined part of the drainpipe and baffle ring [2], adopted as a prototype.

The reasons that impede the achievement of the technical result indicated below when using the known method adopted as a prototype include the fact that in the known method, an increase in the speed of melt water rolling from the surface of the roof drainage elements occurs due to the application of an expensive hydrophobic anti-wettable coating to them, which requires the same great labor costs for systematically maintaining it in working condition, as well as the cost of structural changes in the drainpipe, due to the size HAND in the vertical portion thereof in the area of the tube bend of baffle rings, artificially reducing the diameter of the drain pipe, reducing its design capacity, which increases the probability of clogging and the formation of hard-to-recycle or ice plugs. In addition, coating a narrow strip at the edge of the roof with an anti-wetting coating, i.e. where the ice freezes, which, when thawing, they lose due to the hydrophobic coating, the connection with the roof surface breaks off the roof and leads to roof deformations and other contingencies.

The essence of the invention lies in the use of the hydraulic properties of the fluid flow, when an increase in its speed in frosty air increases the resistance of the fluid to freezing, to protect against icing the surface of the roof drainage elements by artificially reducing the viscosity and increasing the flowability of melt water sliding from the edge of the roof using ionizing radiation allowing, when exposed to water, to violate the spatial uniformity of its density, from which, basically, Xia viscosity and increased melt water speed on drains.

In particular, the placement of a source of ionizing radiation in the form of thin plates made of sylvinite (potassium ore) containing the potassium-40 isotope, located under the edge of the edge of the roof, on its section or along the entire perimeter of the building, in the immediate vicinity of melt water flowing from the roof during its natural decay, it leads to radioactive destruction (radiolysis) of water flowing from the edge of the building roof and the appearance of hydrogen ions H ⁺ and hydroxyl OH ^{- in it} , which disrupt intermolecular bonds and reduce viscosity, as well as surface tension melting water and, as a result, increasing its fluidity, and increasing the speed of movement of the water treated by ionizing radiation through gutters and pipes (or other channels) enhances its resistance to freezing (for example, mountain rivers do not freeze even in severe frosts), which helps protect the surface of the edges of the roofs and drains from icing.

EFFECT: reduced labor costs and increased operational reliability of the roof by providing intensive transportation of melt water treated with ionizing radiation from the edge of the roof edge and down gutters without expensive anti-icing coating and preserving the initial design parameters of roof drainage elements.

The specified technical result in the implementation of the invention is achieved by the fact that in the known method of protecting the surface of the drainage elements of the roof of the building from icing, including artificially increasing the speed of movement of melt water but inclined and vertical drainage elements of the roof of the building, to increase the speed of movement of melt water along the drainage elements of the roof throughout the building’s perimeter (or on its section), thin layers are placed under the edge of the roof edge in the immediate vicinity of the melt water flowing from it Incas facing the edge of the roof edge and the inside of the drainage channels made of sylvinite.

Reducing labor costs and increasing the operational reliability of the roof occurs solely due to the appearance of ions of a different sign in the melt water flowing from the roof, formed by ionizing it under the action of the potassium-40 radioisotope contained in sylvinite plates attached under the perimeter of the roof edge of the building (or parts of the perimeter), which reduce the viscosity of meltwater, increase the speed of its flow along existing gutters and drainpipes and, as a result, increase the resistance of the roof water to freeze, which ensures the protection of the surface of the roof drainage elements from icing.

In addition, the operation of the roof without an anti-wetting coating contributes to the operational reliability of the roof due to the reduction of breakaways and collapse of ice blocks from the edge of the roof edge, which occur due to the loss of tight contact of ice with the roof surface during thawing and the reduction in the probability of blockage of drainpipes due to artificially narrowing their design diameter at the location of the water ring.

The proposed method is illustrated in the drawing.

The drawing shows a diagram of a part of the building with a pitched roof, a gutter, a gutter and thin sylvinite plates attached under the edge of the roof edge (the fastening of the drainage elements is not shown in the diagram).

Information confirming the possibility of carrying out the invention with obtaining the above technical result.

The method is as follows.

Thin plates made of sylvinite 3 containing the radioactive potassium-40 isotope are placed under the edge of the edge of the pitched roof 1 of building 2 at a distance of no more than 5 centimeters from the edge of the edge of the roof 1.

A decrease in viscosity, an increase in fluidity, and a decrease in the surface tension of melt water flowing down from the edge of the roof 1 of building 2 are carried out by ionizing it under the action of the radioactive potassium-40 isotope contained in the sylvinite plates 3 attached (for example, glued) to the building 2 below the edge roof 1 along its perimeter or part of the perimeter.

The fall of radioactive radiation from the natural decay of the potassium-40 isotope onto the droplets and streams of melt water flowing from the edge of the roof edge 1, as well as on the flowing water through the gutter 4, leads to the radiation destruction of water (radiolysis) and the appearance of hydrogen ions H ⁺ and hydroxyl OH in it ^- , which, in turn, reduces the bulk density of melt water, reduces its viscosity and surface tension, increases the fluidity and the rate of separation of drops and streams of water from the edge of the roof 1 and accelerates its movement along the groove 4 and the spillway 5. Quickly draining melt water with a low viscosity does not freeze when the temperature of the atmospheric air changes from positive to negative, i.e. during the formation of icicles and ice, which protects the spillway elements of the roof 1 of building 2 from icing.

The use of sylvinite 3 as a source of ionizing radiation to change the physicochemical properties of melt water allows the mobility of the water flowing from the edge of the roof 1 of building 2, to improve the migration ability and functioning of the drainage systems of roof 1 with minimal cost, because sylvinite 3 is not a scarce and expensive material, and its service life, given the huge half-life of the potassium-40 isotope (1.3 billion years), can be considered unlimited, without the additional cost of periodically maintaining it in working condition.

In addition, the use of sylvinite 3 to achieve a technical result is simple, reliable, affordable and does not require intervention in existing gutter structures, which indicates its increased effectiveness in protecting the surface of the drainage elements of the roof 1 of building 2 from icing.

Thus, the above information indicates the fulfillment when using the claimed invention (method) of the following set of conditions:

- a tool embodying the claimed method in its implementation, is intended for use in industry, namely in construction, and, in particular, when protecting roof drainage elements from icing;

- for the claimed method in the form described in the independent clause of the claims, the possibility of its implementation using the means and methods described in the application or known prior to the priority date is confirmed.

Information sources

1. Patent for the invention of the Russian Federation No. 2571105, E04D 13/076, 2015.

2. Patent for the invention of the Russian Federation No. 2495208, E04D 3/076, 2013, prototype.

Claims (1)

A method of protecting the surface of the drainage elements of the roof of a building from icing, including artificially increasing the speed of meltwater along inclined and vertical drainage elements of the roof of the building, characterized in that to increase the speed of movement of meltwater along the drainage elements of the roof around the entire perimeter of the building (or on its section ) under the edge of the edge of the roof in the immediate vicinity of the melt water flowing from it, thin plates are placed facing the edge of the edge of the roof and the inside of the drainage gutters Made from sylvinite.

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