RU2761917C1 - Tank for non-freezing liquids with an effective permafrost preservation system in the base - Google Patents

Abstract

FIELD: hydrotechnical construction.

SUBSTANCE: invention relates to the field of hydrotechnical construction in the cryolithozone and can be used in the construction of reservoirs, pools, etc. for the storage of non-freezing liquids, in particular, when installing an effective permafrost preservation system in the base. The expected result is achieved by the fact that the conservation system includes a tank on a permafrost base, cooling pipes and channels, as well as a filling layer, while the tank is a set of separate independent sections, the temperature stability and reliability of which are ensured during the operation of sections of the freezing air system due to the fact that the tank is located on a layer of artificial soil filling, in which cooling pipes and channels are laid, supplying winter cold air to the surface of the permafrost base, moreover, the winter air supply channels are located in the middle part of each section or along the outer perimeter of the tank or in the gap between the sections.

EFFECT: increase in the reliability and operational safety of the tank.

3 cl, 2 dwg

Description

The invention relates to the field of hydraulic engineering in permafrost and can be used in the construction of reservoirs, pools, etc. for the storage of non-freezing liquids (natural and artificial solutions, oil products, industrial waste), in particular, when arranging an effective system for the preservation of permafrost in the base.

A known method of cooling (conservation) of the permafrost base of buildings and structures with the help of cooling pipes and channels located in a layer of bedding from sand and gravel soil (Handbook for construction on permafrost soils. L. Stroyizdat. 1977, pp. 246-253). For structures erected in this way, to which the reservoir belongs, there are significant application restrictions. In particular, with air cooling, the diameter of the pipes is taken to be 0.2-0.4, and the pipes are laid parallel to the short side of a rectangular structure. Pipes are placed across the structure to provide optimal natural or forced cooling ventilation. Hence, the disadvantage of this method is the limitation of the planned dimensions of the structure, which from the experience of construction should not be more than 20 m. Accordingly, it is difficult to organize ventilation for large, in terms of, more extended or round structures.

A known system for temperature stabilization of the foundations of structures on permafrost soils (RF patent No. 2416002 MKI E02D 3/115, publ. 10.04.11), containing a water seal, a surge vessel connected to the condenser and connected to them through pipelines supplying and removing the coolant, an evaporator , placed in the foundation soil backfill, characterized in that it contains an additional evaporator with a piping system and a water seal, and both evaporators are located evenly over the entire area of the foundation soil backfill equipped with a layer of thermal insulation, and are connected by means of pipelines through their outlet ends to the upper points the balance vessel, and the supply ends of the main and additional evaporators are connected at the lower point of the condenser and the lower point of the balance vessel, respectively, through the corresponding hydraulic locks. The disadvantage of this technical solution is low environmental friendliness, high complexity and cost due to the use of a coolant in the cooling circuit, and as a consequence of the device of an additional evaporative circuit, the operation of which is carried out in the automatic self-regulation mode - there is a "surplus" of the coolant, then the circuit works, there is no "excess »Coolant - the circuit is not working.

In general, spatially ventilated systems are quite close in technical essence to the claimed solution and can be considered as a prototype.

The invention is based on the task of increasing the stability and reliability of tanks on permafrost foundations and expanding the scope of their possible application, incl. at a very significant size.

The problem is solved by the fact that a reservoir of significant dimensions on a permafrost base is made as a set of separate independent sections. Temperature stability and reliability of operation are ensured due to the fact that the tank is located on a layer of artificial soil bedding, in which cooling pipes and channels are laid, supplying winter cold air to the surface of the permafrost base. Winter air supply ducts are located in the middle of each section or along the outer perimeter of the tank or in the gap between the sections.

Sand and gravel soil, loose coarse-grained soil, incl. crushed stone and other artificial soil.

The cooling ducts can be equipped with fans for forced ventilation, shutters for turning on / off the freezing system, as well as a control and measuring system.

The proposed invention is illustrated by drawings:

FIG. 1 Cross section (diagram) of a tank with a freezing system at the base;

Fig. 2 is a plan (Fig. 1) and a cross-section (Fig. 2) of a tank with a freezing system at the base.

Where: 1 - tank sections; 2 - injection channels, they are also cooling channels; 3 - cooling pipes in bedding; 3а - cooling pipes in the outer compartments of the tank section; 4 - outlet channels between sections; 4а - external outlet channel; 5 - outlet of waste (giving off natural cold) air; 6 - base; 7 - bedding.

The invention is carried out as follows: A bed of coarse soil 7 is poured onto the prepared base 6 of the tank, in which, as this layer is poured, a system of cooling pipes 3 and 3a is laid, connected to the supply 2 and outlet channels 4 and 4a, located on the base along the outer perimeter 4a dumping and in the space between sections 4 of the tank.

Thus, discharge channels are installed in each section of the space between the sections. Supply channels are installed in the middle of each section; cooling pipes are installed in the bed between the inlet and outlet channels. A fan can be installed at the inlet from the atmosphere into each supply channel; at the outlets and inlets of the channels, valves are provided (not shown in the figure), which make it possible to regulate the inlet or outlet of air. The channel and valve control system allows you to open and ventilate the system in the winter (cooling) period and close it in the warm season, as well as in winter during thaws and blizzards, in order to exclude heating, thawing and clogging of cooling pipes and other cavities by snow and ice.

The operation of the tank or its individual sections begins after the base has completely freezed during the construction period and after the restoration of permafrost in case of seasonal or other violations of the required temperature regime. This ensures the thermal stability and reliability of the structure. The control over the temperature regime of the soil of the base of the structure, the operation of the fans, the operation of valves and other parameters is carried out by measuring equipment constantly, regardless of the filling of the containers with liquid. The thermal stability of this structure is ensured by the annual repetition of the winter cooling and freezing cycle of the base.

Equipping with control and measuring equipment should be provided for by the project and is adjusted during the operation of the tank, depending on the results of field observations.

Free and controllable filling of the cooling cavities in the base of the tank with air allows for effective cooling ventilation, significantly reduces the possibility of clogging these cavities with snow and ice plugs, which, as a result, contributes to an increase in the reliability of the proposed structure of the structure.

Claims (3)

1. Conservation system, including a reservoir on a permafrost base, cooling pipes and channels, as well as a bedding layer, characterized in that the reservoir is a set of separate independent sections, the temperature stability and reliability of which are ensured during the operation of sections of the freezing air system due to the fact that the tank is located on a bed of artificial soil, in which cooling pipes and channels are laid, supplying cold winter air to the surface of the permafrost base, and the channels supplying winter air are located in the middle part of each section or along the outer perimeter of the tank or in the gap between the sections. 2. The conservation system according to claim 1, characterized in that sand and gravel soil, loose coarse soil, incl. crushed stone and other artificial soil. 3. The conservation system according to claim 1, characterized in that fans for forced ventilation, valves for turning the freezing system on and off, as well as a control and measuring system can be installed in the cooling channels.

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