RU2424396C1 - Hydrotechnical channel on permafrost soils of slope and cooling device of embankment (versions) - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: hydrotechnical channel comprises a bed formed with a channel bottom and slopes of its sides and arranged higher than the lower border of a seasonally melting layer. The upper side of the channel is formed with a slope, and the lower side - with an embankment, where a frost curtain is arranged by means of seasonally functioning cooling devices installed along the embankment. A cooling device according to the version 1 comprises two external heat exchangers installed along the frost curtain length at the distance from each other, which release heat of a liquid coolant during its natural convection to a cold ambient air, and a soil heat exchanger formed by two freezing pipes. The external heat exchanger represents a tube expander, and the soil heat exchanger comprises two freezing pipes bent along the length and located in the soil along the embankment between tubular expanders and at the specified distance from each other. One freezing pipe is located within the borders of a seasonally melting layer and is hydraulically communicated by an inlet end to a lower part of one tubular expander, and by an outlet end - to a middle part of the other tubular expander. The other freezing pipe is hydraulically communicated by its inlet end to the lower part of the second tubular expander, and by its outlet end - to the middle part of the first expander. The diameter of tubular expanders is more than the diameter of freezing pipes, and drain holes of outlet ends of freezing pipes are arranged at the same level. Connection of freezing pipes ends to at least one tubular expander is made by means of flange joints, every of which is equipped with a gasket of heat insulation material. A cooling device according to the version 2 comprises three external heat exchangers installed serially along the embankment length at the distance from each other and two soil heat exchangers installed serially along the frost curtain in soil. Each external heat exchanger represents a tube expander, and each soil heat exchanger comprises two freezing pipes bent along the length and located in the soil along the embankment between the middle and the extreme tubular expanders and at the specified distance from each other. One freezing pipe of the pair is located within the borders of a seasonally melting layer and is hydraulically communicated by an inlet end to a lower part of the middle tubular expander, and by an outlet end - to a middle part of the extreme tubular expander. The other freezing pipe of this pair is hydraulically communicated by its inlet end to the lower part of the extreme tubular expander, and by its outlet end - to the middle part of the first expander. Drain holes of all (four) outlet ends of two pairs of freezing pipes are arranged at the same level. Connection of freezing pipes ends to extreme tubular expanders is made by means of flange joints, every of which is equipped with a gasket of heat insulation material.

EFFECT: improved reliability of the channel.

3 cl, 5 dwg

Description

The invention relates to hydraulic engineering, and more specifically to the construction of channels on permafrost soils of the slope, in particular when creating a seasonally active channel bypassing the industrial waste storage.

Known buried in permafrost soils of the slope of the hydraulic (water supply, channel discharge, bypass) channel containing a bed formed by the bottom of the channel and the slopes of its sides, and a frozen curtain made of ice in the lower, relative to the slope, side of the channel by means of cooling units [1] .

The disadvantages of the known canal are that when the canal is deepened in permafrost soils, the integrity of the waterproof upper frozen crust (the same: raincoat) is broken in some places, which often leads to the development of intensive filtration of water from the canal and, accordingly, an abnormally fast thawing of permafrost soils. This leads to unacceptable deformations of the channel, and the water filtering from the channel in an unacceptable volume flows into the waste accumulator, which causes an unbalance of the circulating water.

Filtration of water from the canal can be prevented by shielding the canal bed with a waterproof geomembrane. However, in such a channel from the slope from the seasonally thawing layer under the geomembrane will come submerged ground water, which will create pressure from below on the geomembrane, which in the cold season can damage the empty channel and form ice in it. All this will complicate the design of the channel and reduce its reliability.

Water filtration that occurs in an unshielded channel can be prevented by shielding the channel during its operation. Such a decision is provided by RUS-Engineering LLC in the completed work project “Tailings pond of factory No. 8. Elimination of unbalance of circulating waters. Protection of the channel channel from filtering ”[2].

Firstly, in such a thawed channel, the submerged groundwater from the slope will continue to filter into the waste accumulator under the channel, and secondly, canal screening operations can be substantially carried out only in the cold season. All this leads to insufficient reliability of the channel during operation and high costs for its creation.

Known cooling unit (the same: freezing unit), containing an external heat exchanger, which is an outer pipe combined by collectors that transfer heat of the heat-transfer fluid during its forced convection to the cold outside air in the installation, and a soil heat exchanger, which is frozen in the ground and united by collectors (cooling) pipes [3].

In such an installation, if necessary, the freezing tubes may be curved in length and have a variable cross-sectional area. However, for convection of the liquid coolant, each such installation must be equipped with a pump that is constantly operating at low outdoor temperatures, which complicates the operation of the installation.

Known hydraulic channel on permafrost soils of the slope, containing a bed formed by the bottom of the channel and the slopes of its sides and located above the lower boundary of the seasonally thawing layer, which was formed at the surface of the slope before the channel is created. The upper side is formed partially or completely by a slope, and the lower side is formed by an embankment, the height of which provides a passage through the channel of the maximum estimated water flow. A permafrost curtain is made in the embankment, which is closed with a waterproof top layer (cloak) of permafrost slope soils by means of seasonally operating cooling units installed along the embankment. Each installation is made in the form of a freezing column containing an external heat exchanger that gives off heat of the heat-transfer fluid during its natural convection to cold outside air, and a ground heat exchanger formed by a freezing pipe buried in permafrost soils [4, example 2].

The disadvantages of such a channel selected as a prototype, which impede the receipt of the technical result indicated below during the creation and operation of the channel, are as follows.

1. Freezing columns usually have a height of at least 8-10 m and are arranged in increments of about 2 m, which leads to a large total length of freezing columns. In this case, the sum of the lengths of only the soil parts of the freezing columns is more than three times the length of the permafrost curtain. This circumstance leads to a high consumption of metal and liquid coolant, therefore, high costs both when performing the permafrost curtain, and during its operation.

2. When deep freezing columns are buried in permafrost soils, the integrity of the waterproof raincoat may be impaired. This will cause the development of filtration from the water channel and, accordingly, intensive thawing of permafrost soils, which reduces the reliability of the channel during operation.

3. The permafrost curtain created by the freezing columns is not uniform in length along the lateral soil surface of which alternates with hollows and protrusions, which are formed by closed frozen cylinders. In this case, the total length of the depressions or protrusions is close to the total length of the soil parts of the columns, which increases the cost of creating a permafrost curtain (protrusions) and reduces its reliability (depressions) during operation.

4. The implementation of the freezing columns is associated with the drilling of wells, which complicates the work when creating a permafrost curtain.

A known cooling installation, including an external heat exchanger, which is a tubular expander, which transfers the heat of the liquid coolant during its natural convection in the installation to cold outside air, and a ground heat exchanger, which is a freezing pipe bent along the length of the soil, the diameter of which is less than the diameter of the tubular expander. The freezing pipe inlet (pressure) end is hydraulically connected to the lower part of the tubular expander, and the output (drain) end is connected to the middle part of the same tubular expander [5].

The reason that impedes the obtaining of the technical result indicated below when using the known cooling unit is its complexity and insufficient efficiency when performing and operating a linear permafrost curtain, for example, when performing a permafrost curtain in an embankment located on permafrost soils. At the same time, the length of the permafrost curtain created by one cooling installation usually does not exceed 7-10 m, which is associated with high costs when performing a large number of cooling installations along the entire length of the permafrost curtain and their operation. All this is due to the fact that the freezing pipe of the cooling installation in the soil in the middle part is bent 180 degrees and returned back to its tubular expander.

Additionally, the coefficient of thermal conductivity of steel λ = 45.4 W / (m · K), which is about 30-40 times higher than the thermal conductivity of soils. Therefore, in the warm season, the heat of outside air and solar radiation is introduced into the frozen curtain through steel freezing pipes, which causes the frozen curtain to melt from the side of the freezing pipe. This reduces the overall efficiency of the cooling unit during the creation and operation of the channel.

The task, which is claimed by the claimed hydraulic channel on permafrost soils of the slope and cooling installation of the embankment (options), is to increase the reliability of the channel and save money during its creation and operation.

A single technical result achieved by the implementation of the claimed group of inventions is as follows:

- reduced consumption of metal and liquid coolant;

- prevented the violation of the integrity of the waterproof raincoat;

- in the permafrost curtain, the total length of the closing depressions is reduced by about three times;

- simplified work on the creation of a permafrost curtain;

- prevented summer thawing of the permafrost curtain from the side of the freezing pipes.

The specified technical result is achieved by the fact that in the hydraulic channel on permafrost soils of a slope containing a bed formed by the bottom of the channel and the slopes of its sides and located above the lower boundary of the seasonally thawing layer, while the upper side of the channel is partially or completely sloped, the lower side of the channel is formed by a bulk the height of which provides a passage through the channel for the estimated water flow, and in the embankment, seasonally operating cooling units installed along the embankment are frozen the curtain, which is closed with a waterproof top layer of permafrost soils of the slope, and the cooling unit contains an external heat exchanger, which transfers heat of the heat-transfer fluid during its natural convection to the cold outside air, and a soil heat exchanger formed by a freezing pipe. According to the invention, the cooling installation comprises at least two external heat exchangers installed along the length of the embankment at a predetermined distance from each other, each of which is a tubular expander, and a soil heat exchanger, which is two freezing pipes curved along the length, located in the ground along embankments between tubular expanders and at a given distance from each other. One freezing pipe is located within the seasonally defrosting layer and is hydraulically communicated by the inlet (pressure) end with the lower part of one (first) tubular expander, and the outlet (drain) end with the middle part of the other (second) tubular expander. Another freezing pipe is located within the embankment and is hydraulically communicated with the inlet end with the lower part of the second tubular expander, and the outlet end with the middle part of the first expander. The diameter of the tubular expanders is larger than the diameter of the freezing ones, and the drain holes of the outlet ends of the freezing tubes are located at the same level.

The location of one freezing pipe along the embankment within the seasonally thawing layer, which was formed on the day surface of the slope before the channel was created, allows the frozen curtain to close with a waterproof raincoat, and the location of the other freezing pipe within the embankment enhances the freezing of the embankment with outside cold air. The implementation of two external heat exchangers and their hydraulic connection with freezing pipes according to the above rules provides for the natural convection of the liquid coolant and its cooling with cold outside air. All this substantially ensures the achievement of the above technical result.

The indicated technical result is also achieved by the fact that the cooling installation of the embankment (option 1) contains two external heat exchangers installed along the length of the permafrost curtain at a predetermined distance from each other, each of which is a tubular expander that transfers the heat of the liquid coolant during its natural convection to the cold outdoor air, and a soil heat exchanger, which is two freezing pipes curved along the length, located in the soil along the embankment between the tubular at a given distance from each other. At least one freezing pipe is located within the seasonally defrosting layer and is hydraulically connected by the inlet (pressure) end with the lower part of one (first) tubular expander, and the outlet (drain) end with the middle part of the other (second) tubular expander. Another freezing pipe is hydraulically connected by the inlet end to the lower part of the second tubular expander, and the outlet end to the middle part of the first expander. The diameter of the tubular expanders is larger than the diameter of the freezing ones, the drain openings of the outlet ends of the freezing pipes are located at the same level, and the ends of the freezing pipes are connected to at least one tubular expander by means of flange connections, each of which is provided with a gasket of heat-insulating material.

It is the implementation of the cooling installation with two external heat exchangers and their hydraulic connection with freezing pipes according to the indicated rules that provides the natural convection of the liquid coolant and its cooling with cold outside air. At the same time, the heat-insulating flange joints prevent the introduction of external summer heat through the freezing pipes into the permafrost curtain and simplify the location of the drain holes of the outlet ends of the freezing pipes at the same level both when performing the cooling installation and during its operation. All this contributes to the achievement of the above technical result.

The specified technical result is also achieved by the fact that the cooling installation of the embankment (option 2) contains three external heat exchangers installed sequentially along the length of the embankment at a predetermined distance from each other, each of which is a tubular expander that transfers heat from the liquid coolant during its natural convection to the cold outdoor air, and two soil heat exchangers located successively along the permafrost curtain in the soil, each of which is a pair of curved lengths freezing pipes located in the soil along the embankment between the middle and extreme tubular expanders and at a given distance from each other. At least one freezing pipe of the pair is located within the seasonally active layer and is hydraulically connected by the inlet (pressure) end with the lower part of the middle tubular expander, and the output (drain) end with the middle part of the extreme tubular expander. Another freezing pipe of this pair is hydraulically connected by the inlet end to the lower part of the same extreme tubular expander, and the output end to the middle part of the middle expander. The drain holes of all (four) outlet ends of both pairs of freezing pipes are located at the same level, the ends of the freezing pipes are connected to the extreme tube expanders by means of flange connections, each of which is provided with a gasket of heat-insulating material, and the diameters of the middle tube expander D _cp , of the extreme tube extenders D _kp and freezing pipes d _t satisfy the condition: D _cp > D _kp > d _t .

It is the implementation of a cooling installation with three external heat exchangers and their hydraulic connection with freezing pipes according to the indicated rules that provides the natural convection of the liquid coolant and its cooling with cold outside air. At the same time, the heat-insulating flange joints, as in the cooling system with two external heat exchangers, prevent the introduction of external summer heat through the freezing pipes into the permafrost and simplify the location of the drain openings of the outlet ends of the freezing pipes at the same level both during the implementation of the cooling installation and during its operation . All this contributes to the achievement of the above technical result.

The analysis of the prior art by the applicant made it possible to establish that there are no analogues that are characterized by sets of features identical to all the features of the claimed hydraulic channel on permafrost slope soils and cooling installation of the embankment (options). Therefore, each of the claimed invention meets the condition of patentability "novelty."

The search results for well-known solutions in this and related technical fields in order to identify features that match the features of each claimed invention showed that they do not all follow explicitly from the prior art. From the prior art determined by the applicant, the influence of the essential features of each of the claimed inventions of the transformations on the achievement of the specified technical result is not known. Therefore, each of the claimed inventions meets the condition of patentability "inventive step".

In this patent application, the unity of invention has been met. Indeed, the new cooling unit was used in the creation and operation of the channel. This cooling unit is intended for the device (manufacturing) of a structurally new permafrost curtain in the lower side of the channel. The claimed inventions solve the same problem - improving the reliability of the channel and saving money on its creation and operation.

The invention is illustrated by drawings, which depict:

figure 1 - hydraulic channel, laid on permafrost soils of the slope bypassing the tailings;

figure 2 is a section aa in figure 1;

figure 3 is a section bB in figure 2, example 1;

figure 4 - node a in figure 3;

figure 5 is a section bB in figure 2, example 2.

Example 1 (Figs. 1-4). Channel 1 (hereinafter: the channel) is an artificial channel of a seasonal watercourse 2, which, under conditions of permafrost soil 3, is laid around the bulk gully-ravine tailings 4, the capacity of which is formed by a channel dam 5 and a water-lifting dam 6, which creates a regulating capacity 7 on watercourse 2. The tailing pond 4 is protected from surface runoff from the left-bank slope 8 by a mountain ditch 9, and from the right-bank slope 10 is directly protected by a channel, which, by means of the mating structure 11 oedinen with watercourse 2.

The channel contains a bed 12, which is located above the day surface 13 of the slope 10 and is formed by the aligned bottom 14 of the channel and the slopes 15 and 16 of its sides, respectively, of the top 17 and bottom 18. The top side 17 is completely formed by slope 10, so the slope 15 is part of the day surface 13. The lower side 18 is formed by the embankment 19, the height of which provides a passage through the channel of the estimated water flow. In the embankment 19, by means of seasonally operating cooling units 20 installed along the embankment, a permafrost curtain 21 is made, which is closed with a waterproof top layer, i.e. cloak, 22 permafrost soils 3 slopes 10.

The cooling unit 20 in embodiment 1 (FIGS. 3 and 4) comprises two external heat exchangers installed along the embankment 19 at a predetermined distance l ₁ from each other, each of which is a tubular expander 23 and 24, and one soil heat exchanger, which consists of two curved along the length of the freezing pipes 25 and 26. These pipes 25 and 26 are located in the ground along the embankment 19 between the tubular expanders 23 and 24 and at a given distance l ₂ from each other.

The freezing pipe 25 is located within the seasonally defrosting layer 27, which was formed at the day surface 13 of the slope 9 before the channel was created, and is hydraulically communicated by the inlet (pressure) end 28 with the lower part of the tubular expander 24, and the outlet (drain) end 29 with the middle part of the tubular expander 23. The freezing tube 26 is located within the embankment 19 and is hydraulically communicated with the inlet end 30 with the lower part of the tubular expander 23, and the outlet end 31 with the middle part of the tubular expander 24. The diameter of the pipe taper expanders 23 and 24 are larger than the diameter of the freezing pipes 25 and 26, and the drain holes of the outlet ends 29 and 31 of the freezing pipes 25 and 26 are located at the same level 32.

The inlet and outlet ends of the freezing pipes 25 and 26 were connected to the tube expanders 23 and 24 by means of heat-insulating flange joints 33, each of which is provided with a gasket 34 made of heat-insulating material, for example, fluoroplastic (venyl plastic) PMB, and bolts 35 made of polymer material. If necessary, flange connections can be equipped with mounting rings, allowing you to change the thickness of the connection (rings in figure 4 are not shown). This allows for uneven deformation along the length of the embankment 19 to install tubular expanders 23 and 24, therefore, the drain holes of the output ends of the freezing pipes 25 and 26 at the same level.

In the drawings, the positions denote other elements of structures and the environment, namely:

36 - nutritional groove;

37 - drain pipe;

38 - the level of kerosene in the tubular expander in the summer;

39 - level of kerosene in a tubular expander in winter;

40 - level (plane) of comparison;

41 - cap with thread;

42 - drain hole;

43 - the upper boundary of permafrost soils before the creation of the channel;

44 - the upper boundary of frozen soils, established after the creation of the channel;

45 - maximum water level in the channel;

46 - a protective box (summer).

The channel is being constructed in the following sequence.

First, frost tubes 25 are installed along the length of the channel within the seasonally defrosting layer 27, after which the embankment 19 is erected to the level of the frost tubes 26 to freeze the soil in the cold season with natural cold outside air, while the soil is saturated with water through the nutrient grooves 36. Then, freezing tubes 26 are installed, the embankment 19 is raised to its full height, tubular expanders 23 and 24 are installed, and cooling units 20 are used along the entire length of the embankment 19 during the cold season. The combined effect of the cold outside air on the embankment 19 and the freezing tubes 25 and 26 provides permafrost curtain 21 and its qualitative closure with a waterproof raincoat of permafrost 3, and almost without depressions of the closure of particularly frozen cylinders around the freezing pipes 25 and 26.

The feature of the channel is as follows.

1. In the warm season, water enters the canal from the regulating capacity of the watercourse 7, as well as sediment water flowing into the canal from the slope 10. The waterproof raincoat 23 and the frozen curtain 21 prevent the filtering of water from the canal around the entire perimeter of its live section. At the same time, the water temperature in the canal is almost constantly lower than the temperature of the atmospheric air blowing over the slope; therefore, the thickness of the seasonally thawing layer 27 in the canal usually does not exceed the thickness of such a layer 27 on slope 10. Under such conditions, the canal's operation cannot affect the waterproofness of the cloak.

In the cold season, the flow of water from the control tank into the canal ceases, and the seasonally thawing layer 27 of slope 10 and embankment 19 melted in the warm season, freezes. At the same time, the channel accumulates in itself the ice formed from the permafrost water of the seasonally spreading layer 27. The formation of ice in the channel can be prevented by the removal of ice-forming water from the channel by means of a drain pipe 37 made with perforation, mainly made of polyethylene.

The passage through the spring water flood channel is carried out with the implementation of the measures established by the project.

2. The principle of operation of the proposed cooling unit 20 is based on the well-known property of a liquid coolant, such as kerosene, to change the density with temperature. So? kerosene when cooled by one degree reduces the volume and increases the density by 0.11%. Therefore, the free surface of kerosene in hydraulically connected tubular expanders 23 and 24 in winter drops from summer level 38 to winter level 39. Moreover, in winter at any ground level (plane) of comparison 40 (Fig. 4), which intersects the ends of freezing pipes 25 and 26, hydrostatic the pressure of the colder kerosene in the pressure (input) ends 28 and 30 will be higher than the hydrostatic pressure of the less cold kerosene in the drain (output) ends 29 and 31. It is this circumstance that provides natural convection of kerosene in the cooling Settings 20 at which the outer surface through the tubular expanders 23 and 24 occurs returns cold outside air heat rendered kerosene from the soil.

Filling the cooling unit 20 with kerosene is carried out after removing the cap with thread 41 from one of the tubular expanders with the drain hole 42 open on the other tubular expander. If necessary, the height position of the tube expanders 23 and 24 by means of flange connections 33 is brought into correspondence with one another.

The efficiency of expanders 23 and 24 can be increased by their finning - ribs are not shown in the drawings. The geometric parameters of the tubular expanders 23 and 24 and the freezing tubes 25 and 26 of the cooling installation, including the distances l ₁ and l ₂ , the volume of kerosene and the position of its levels in the installation under different conditions, as well as the cooling capacity of the installation, are determined during the design by thermal engineering calculations. At the same time, well-known techniques are adapted, for example, from the source [5].

Example 2 (figure 5). The difference of the channel from the above described in example 1 is that the creation of a permafrost curtain 21 in the embankment 19 is carried out by means of a cooling unit 47, made according to option 2.

The cooling installation 47 comprises three external heat exchangers and two ground heat exchangers arranged in series along the embankment 19 in series along the length of the embankment 19 at a predetermined distance l ₁ from each other.

Each of the external heat exchangers is a tubular expander, respectively, 48, 49 (medium) and 50, which gives off the heat of the liquid coolant during its natural convection to the cold outside air.

Each of the soil heat exchangers is a pair of bent along the length of the freezing pipes 51 and 52. These pipes 51 and 52 are located at a predetermined distance 1 ₂ from each other in the ground between two adjacent tubular expanders 48 and 49, as well as between tubular expanders 49 and 50 .

The freezing tube 51 of the pair is located within the seasonally defrosting layer 27 and is hydraulically communicated by the inlet (pressure) end 53 with the lower part of the middle tubular expander 49, and the outlet (drain) end 54 with the middle part of the extreme tubular expander 48 or 50. Another freezing pipe 52 pairs are located within the embankment 19 and are hydraulically connected by the inlet end 55 to the lower part of the extreme tubular expander 48 or 50, and the output end 56 to the middle part of the middle tubular expander 49. Drain holes all x four output ends of both pairs of freezing pipes 51 and 52 are located on the same level 32.

Structurally, the inlet ends 53 of both pipes 51 are expediently combined into one pipe (see FIG. 5). The inlet ends 56 of both pipes 52 can also be combined into one pipe — in FIG. 5, these ends 56 are shown separately.

The ends 54 and 55 of the freezing pipes 51 and 52 are connected to the extreme tube expanders 48 and 50 by means of flange connections 33 (Fig. 4), each of which is provided with a gasket 34 of heat-insulating material and bolts 35 of polymer material.

The diameters of the middle tubular expander D _cp , the extreme tubular expanders D _cr and freezing pipes d _t satisfy the condition:

D _cp > D _cr > d _t . In this case, D _cp ≈2D _cr .

For the warm season, the extreme tubular expanders 48 and 50 are provided with protective boxes 46 (FIG. 3), and the middle tubular expander 49 with a protective tent (not shown).

The construction and operation of the channel are carried out in the same way as in example 1, while the principle of operation of the cooling unit 47 and its operation are similar to the cooling unit 20.

The above information shows that when implementing the claimed group of inventions, the following conditions are met:

- means embodying the invention in their implementation, are intended for use in industry, namely: in hydraulic construction in the Far North;

- for the claimed inventions in the form as described in the independent claims, the possibility of their implementation is confirmed;

- means embodying the invention in their implementation, are able to provide the specified technical result.

Therefore, the claimed invention meets the condition of patentability "industrial applicability".

Various modifications and changes may be made to the present invention without departing from the scope of the invention. For example, in cooling installations 20, the location of freezing pipes 25 and 26 can be changed, and in cooling installations 47, the location of freezing pipes 51 and 52 can be changed.

Information sources

1. Yagin V.P., Vaikum V.A., Povarenkin V.A., Davydov I.A., Neyland N.N. To the issue of placement of solid water-containing wastes of thermal power plants and other industries // Hydrotechnical construction, 1998, No. 6.

2. Tailing dump of factory No. 8. Elimination of unbalance of circulating waters. Protection of the channel channel from filtering. Working documentation. Volume 1. Explanatory Note // Design Directorate. Branch of RUS-Engineering LLC in Krasnoyarsk, 2007.

3. Guide to the construction of permafrost. Ed. Yu.Ya. Veli, V.I. Dokuchaev, N.F. Fedorov. L., Stroyizdat, Leningrad. Separation, 1977. S. 246-252.

4. Patent of the Russian Federation No. 2385985, cl. ЕВВ 5/02, publ. 04/10/2010.

5. Guidance on the design, construction and operation of artificial structures of roads on watercourses with ice / Voronezh Ing. builds. Inst. M .: Transport, 1989. Appendix 9.

Claims (3)

1. The hydraulic channel on permafrost soils of the slope, containing a bed formed by the bottom of the channel and the slopes of its sides and located above the lower boundary of the seasonally thawing layer, which was formed at the day surface of the slope before the channel was created, while the upper side of the channel is partially or completely formed by the slope, the lower side the channel is formed by an embankment, the height of which provides a passage through the channel of the estimated water flow, and in the embankment, by means of seasonally operating cooling units installed along the embankment, filled with a frozen curtain, which is closed with a waterproof top layer of permafrost soils of the slope, and the cooling unit contains an external heat exchanger, which transfers the heat of the liquid coolant during its natural convection to cold outside air, and a soil heat exchanger formed by a freezing pipe, characterized in that the cooling installation contains installed the length of the embankment at a given distance from each other, at least two external heat exchangers, each of which represents a tubular expander, and a soil heat exchanger, which is two freezing pipes curved along the length, located in the soil along the embankment between the tubular expanders and at a predetermined distance from each other, while one freezing pipe is located within the seasonal defrosting layer and is hydraulically communicated with the input (pressure) the end with the lower height part of one (first) tubular expander, and the output (drain) end - with the middle part of the other (second) tubular expander, the other freezing The pipe is located within the embankment and is hydraulically communicated with the inlet end with the lower part of the second tubular expander and the outlet end with the middle part of the first expander, the diameter of the tubular expanders being larger than the diameter of the freezing pipes, and the drain holes of the outlet ends of the freezing pipes are at the same level. 2. The cooling installation of the embankment, characterized in that it contains two external heat exchangers installed along the length of the permafrost curtain at a predetermined distance from each other, each of which is a tubular expander that transfers heat from the heat-transfer fluid during its natural convection to cold outside air, and a ground heat exchanger , which is two curved along the length of the freezing pipe located in the ground along the embankment between the tubular expanders and at a given distance from each other uga, while at least one freezing pipe is located within the seasonally thawing layer and is hydraulically communicated by the inlet (pressure) end with the lower part of one (first) tubular expander, and the outlet (drain) end with the middle part of the other (second ) of a tubular expander, another freezing pipe is hydraulically communicated by the inlet end with the lower part of the second tubular expander, and the output end with the middle part of the first expander, and the diameter of the tubular expanders is larger than the diameter for freezing pipes, drain openings of the outlet ends of the freezing pipes are located at the same level, and the ends of the freezing pipes are connected to at least one tubular expander by means of flange connections, each of which is provided with a gasket of heat-insulating material. 3. The cooling installation of the embankment, characterized in that it comprises three external heat exchangers installed sequentially along the length of the embankment at a predetermined distance from each other, each of which is a tubular expander that transfers the heat of the heat-transfer fluid during its natural convection to cold outside air, and arranged in series along the permafrost curtain in the ground are two soil heat exchangers, each of which is a pair of freezing pipes bent along the length, located in soil along the embankment between the middle and extreme tubular expanders and at a predetermined distance from each other, at least one freezing pipe of the pair is located within the seasonally defrosting layer and hydraulically communicated with the inlet (pressure) end with the lower part of the middle tubular expander, and the output (drain) end - with the middle part of the extreme tubular expander, another freezing pipe of this pair is hydraulically connected by the inlet end with the lower part of the same extreme tubular expander, and the output end is with the middle part of the middle expander, and the drain holes of all (four) output ends of both pairs of freezing pipes are located at the same level, the ends of the freezing pipes are connected to the extreme tube expanders by means of flange connections, each of which is provided with a gasket of heat-insulating material, and the diameters of the middle tubular expander D _cp , extreme tubular expanders D _cr and freezing pipes d _t satisfy the condition: D _cf > D _cr > d _t .

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