RU83779U1 - COOLED FACILITY BASE - Google Patents

Abstract

1. The cooled base of structures, containing a soil dump with a layer of thermal insulation located in its upper part, as well as a seasonal cooling system of several gravitational heat pipes, each of which has a condensation zone, a transport zone and an evaporation zone and is sealed and consists of two sections moreover, one of these sections, in which the evaporation zone is located, is located at an angle to the horizon of not more than 10 ° and is located completely in a soil dump below the thermal insulation layer, and the other section, in the transport zone and the condensation zone are located vertically or are deviated from the vertical by no more than 30 ° so that the condensation zone is completely above the surface of the soil dumping, characterized in that the seasonal cooling system additionally contains containers of elastic material with cold storage a substance placed in a soil dump below the thermal insulation layer near the sections of gravitational heat pipes in which their evaporation zones are located. ! 2. The cooled base according to claim 1, characterized in that each container with a cold storage substance is enclosed in a rigid frame. ! 3. The cooled base according to claim 1 or 2, characterized in that the containers with the cold-accumulating substance are placed at the same level with the sections of gravity heat pipes containing evaporation zones. ! 4. The cooled base according to claim 3, characterized in that the container with the cold-accumulating substance is made in the form of a vessel with a neck having a hermetically sealed lid. ! 5. The cooled base according to claim 1 or 2, characterized in that the capacity of the battery

Description

The proposed utility model relates to the field of construction, namely, to the foundations and foundations of various structures being erected in areas of the Far North with permafrost soil, more specifically, to the cooled foundation of structures.

Features of the foundations of structures erected on permafrost are determined by specific climatic conditions in high latitude regions of the North. In winter, the air temperature there is quite low for a long time and often reaches minus 40 °. However, snow cover and low thermal conductivity of the soil do not allow it to freeze deeply and severely. In the summer, frozen ground thaws, and this creates the threat of deformation of the foundations and the destruction of structures. Therefore, there is a need to extend the frozen state of the soil in the summer. This is achieved by additional cooling the soil with the help of cooling units, mainly seasonal effects. These plants, in particular gravitational heat pipes, additionally cool the soil in winter and do not work in summer. With the help of such devices it is possible to significantly increase the bearing capacity of the foundations of structures.

The known design of the bulk cooled base of structures according to the patent of the Russian Federation for the invention No. 2157872 (publ. 10/20/2000 [1]), containing cooling pipes connected to the condenser part, and insulation layers placed above them and filling the soil. At the same time, cooling pipes filled with low-boiling liquid are placed inside protective pipes made with a blanked end on one side and an open end on the other, and filled with heat-conducting liquid. Protective pipes are located under the soil filling and thermal insulation layer with a slope of 0 ° -10 ° to the longitudinal axis of the base towards the muffled ends, and the open ends are outside the soil filling contour.

With a decrease in the temperature of atmospheric air and the temperature of the soil, the circulation of the gas-liquid flow in the system begins: the condenser part is cooling pipes, which is accompanied by the removal of heat from the soil.

This design has a low thermal efficiency due to the large length of the vapor-liquid tract. The base of the structure is melted, especially in the area where the pipes enter the soil, even during the spring and autumn frosts. For the same reason, it is difficult to start the device in operation, especially with daily temperature fluctuations. In addition, the cooling pipes are interconnected, and the failure of one pipe disrupts the circulation of the gas-liquid flow of the entire system, which significantly reduces the reliability of this design.

Also known is the cooled base of structures according to the patent of the Russian Federation for utility model No. 33955 (published on November 20, 2003 [2]), containing a soil dump with

in its upper part, a layer of thermal insulation, as well as a seasonal cooling system of several gravitational heat pipes, each of which has a condensation zone, a transport zone and an evaporation zone and is sealed and consists of two sections. One of these sections, in which the evaporation zone is located, is located at an angle to the horizon of no more than 10 ° and is placed completely in the dump below the thermal insulation layer. Another section in which the transport zone and the condensation zone are located is vertically or deviated from the vertical by no more than 30 °, so that the condensation zone is completely above the surface of the dump.

This design has a higher thermal efficiency and reliability compared to the previous one due to the fact that the length of the vapor-liquid path of each pipe is small and the fact that leakage at any point destroys only one pipe, but not the entire cooling system.

However, this design of the cooled base has not enough high thermal efficiency and reliability. As in the previous design, the thermal inertia of the filling ground frozen in winter may not be sufficient to maintain it solid in the summer, which will lead to a decrease in the bearing capacity of the base. This drawback can only be partially compensated by an increase in the number of pipes in the seasonal cooling system due to a certain decrease in the temperature of the frozen soil, however, reliability decreases as the number of active elements, such as thermal elements, increases.

pipes. It is also obvious that this entails an increase in material costs for the construction of the foundation.

The cooled base of structures according to the patent [2] is the closest to the proposed one.

The technical solution for the proposed utility model is aimed at achieving a technical result consisting in increasing the thermal efficiency and bearing capacity of the base of the structure with a simultaneous increase in reliability and lower material costs for its construction.

The proposed cooled base of structures, as well as the closest known to it, contains soil filling with a layer of thermal insulation located in its upper part, as well as a seasonal cooling system of several gravitational heat pipes, each of which has a condensation zone, a transport zone and an evaporation zone and made tight and consisting of two sections. One of these sections, in which the evaporation zone is located, is located at an angle to the horizon of not more than 10 ° and is placed completely in a soil dump below the thermal insulation layer. The other section, in which the transport zone and the condensation zone are located, is located vertically or deviated from the vertical by no more than 30 °, so that the condensation zone is completely above the surface of the soil dump.

To achieve the specified technical result in the proposed base, in contrast to the closest known to it, the seasonal cooling system additionally contains containers of elastic material with a cold-accumulating substance, placed in a soil dump

below the thermal insulation layer near the heat pipe sections in which their evaporation zones are located.

The presence of such containers at their indicated location allows them to be effectively cooled during the cold season to maintain, thanks to their presence, low temperature of the soil in the warm season without a smaller number of heat pipes, which indicates an increase in the thermal efficiency of the device. Accordingly, this allows you to provide the required bearing capacity of the base of the structure without increasing or decreasing the number of heat pipes that are active elements, and, therefore, at the same time improve reliability. The increase in the bearing capacity and ensuring its required level are achieved not due to the complexity of the cooling system due to the addition of its active elements, but due to the structurally simple passive elements, which are containers with a cold-accumulating substance. Obviously, this also contributes to lower material costs due to the significantly lower cost of the mentioned capacity compared to the cost of a heat pipe. The implementation of containers for a cold-accumulating substance from an elastic material allows them to remain airtight during solidification and further cooling of a already solidified substance due to an increase in its volume and thereby prevent a negative impact on the reliability of the inclusion of additional elements in the composition of the structure, which are the mentioned containers.

Each cold storage container can be enclosed in a rigid frame. The presence of a rigid frame protects the tank with the accumulating cold substance from

damage and therefore further increases the reliability of the cooling system and the base as a whole.

In addition, a container made of an elastic material with a cold-accumulating substance, enclosed in a rigid frame, retains its shape even when inclined with respect to the horizon. This allows for a unified soil layout for parts of heat pipes containing evaporation zones, and for containers with storage material.

The cold storage substance can be a liquid that hardens at a temperature of 0 ° - minus 3 ° C. This choice is most appropriate given that the water contained in the soil has a freezing point of 0 ° C.

The rational choice of a cold storage substance is water, because ice has a high specific heat of fusion.

A container with a cold storage substance can be made in the form of a vessel with a neck having a hermetically sealed lid. This allows you to fill the tank both in advance and during the construction of the cooled base.

Tanks with a cold storage substance can be placed at the same level as the sections of the heat pipes containing the evaporation zone, alternating with them in a direction parallel to the surface of the base, and at different levels above or below the indicated sections. Depending on the choice of placement of containers with a cold storage substance, the largest area of the cooled base can be provided with a limited number of heat pipes or the largest

depth of soil maintained in a frozen state.

The proposed solution is illustrated by the drawings of figure 1 - figure 3:

- figure 1 and figure 3 shows the construction of the cooled base in a vertical section for two different cases of mutual placement of the evaporation zones of heat pipes and containers with a cold storage substance;

- figure 2 shows a view aa of figure 1.

In accordance with figures 1, 3, structure 1 is installed on a cooled base, including a soil bed 2, a heat-insulating layer 3, and a seasonal cooling system. The latter contains several gravitational heat pipes 12, each of which is sealed and consisting of two sections. One of these sections, in which the evaporation zone 6 is located, is located at an angle to the horizon of not more than 10 ° and is located completely in the soil dump 2 below the thermal insulation layer 3. Another section, in which transport zone 2 and condensation zone 4 are located, is located vertically or deviated from the vertical by no more than 30 °. In this case, the condensation zone 4, in which the pipe 12 is equipped with the fins shown in Fig. 1, is completely above the surface of the soil dump 2.

The seasonal cooling system also contains containers 8 of elastic material (for example, rubber or plastic) with a cold-accumulating substance 9. These containers are placed in a soil dump 2 below the thermal insulation layer 3 near those sections of gravitational heat pipes 12, in

which are their evaporation zone 6 (see figure 2, depicting in plan the arrangement of the evaporation zones 6 of the heat pipes and containers 8 with the cold-accumulating substance 9). Each container 8 is enclosed in a rigid frame 7. The latter is made in the form of a formwork or pipe made of metal or plastic.

The mutual arrangement of the evaporation zones 6 of the heat pipes 12, shown in FIG. 1 and FIG. 2, is only one of the particular cases. Other special cases of mutual placement are possible both at one level and at different levels. For example, instead of the arrangement shown in FIG. 2, the rows of alternating evaporation zones 6 and containers 8 are mutually displaced, the arrangement of the same rows without offset can be realized when the tanks and evaporation zones of one row are opposite the tanks and evaporation zones of the other row, respectively.

The base of FIG. 3 differs from that shown in FIG. 1 in that the containers 8 and the evaporation zones 6 of the heat pipes are not located at one but at different levels, namely, the tanks 8 are located above the sections of the heat pipes containing the evaporation zones 6.

The containers 8 located in FIG. 1 between the evaporators 8 of the heat pipes 12, and in FIG. 3 above them, are vessels made of elastic material and limited by rigid frames 7. The tanks have a filling neck 10 that is sealed with a cap 11 after completion refueling with a cold-accumulating substance 9. The latter has the property of changing its state of aggregation from liquid to solid at a temperature of 0 - minus 3 °. As such a liquid, in particular, water can be used.

The upper part 4 of each gravitational heat pipe 12 has a fin and serves as an air heat exchanger or condenser for the heat carrier charged into the heat pipe. The lower part 6 of the heat pipe, located in the soil dump 2, is an evaporator. The heat of the soil is absorbed by the evaporator, transferred up to the condenser by the vapor of the refrigerant and is given to the surrounding air washing the fins. In the cold season, heat pipes pump the heat of the soil of dumping 2 into the surrounding air. Soil and substance 9 in containers 8, which were previously in a liquid state, are cooled and hardened. In this case, the latent heat of solidification of the liquid 9 is also transferred to the air. Then there is a deeper cooling of the soil and frozen liquid 9 in tanks 8 with decreasing temperature. In the warm season, 12 seasonal heat pipes do not work. Under the influence of external climatic factors and heat supply from building 1, the soil is heated up in dumping 2. However, the thawing of the frozen substance 9 in tanks 8 is accompanied by the absorption of a large amount of heat coming from outside and therefore slows down the transition of the soil of dumping 2 to an unfrozen state. This ensures a year-round high bearing capacity of the base of the structure.

Information sources

1. Patent of the Russian Federation for the invention No. 2157872, publ. 10/20/2000.

2. Patent of the Russian Federation for utility model No. 33955, publ. 11/20/2003.

Claims (8)

1. The cooled base of structures, containing a soil dump with a layer of thermal insulation located in its upper part, as well as a seasonal cooling system of several gravitational heat pipes, each of which has a condensation zone, a transport zone and an evaporation zone and is sealed and consists of two sections moreover, one of these sections, in which the evaporation zone is located, is located at an angle to the horizon of not more than 10 ° and is located completely in a soil dump below the thermal insulation layer, and the other section, in the transport zone and the condensation zone are located vertically or are deviated from the vertical by no more than 30 ° so that the condensation zone is completely above the surface of the soil dumping, characterized in that the seasonal cooling system additionally contains containers of elastic material with cold storage a substance placed in a soil dump below the thermal insulation layer near the sections of gravitational heat pipes in which their evaporation zones are located. 2. The cooled base according to claim 1, characterized in that each container with a cold storage substance is enclosed in a rigid frame. 3. The cooled base according to claim 1 or 2, characterized in that the containers with the cold-accumulating substance are placed at the same level with the sections of gravity heat pipes containing evaporation zones. 4. The cooled base according to claim 3, characterized in that the container with the cold-accumulating substance is made in the form of a vessel with a neck having a hermetically sealed lid. 5. The cooled base according to claim 1 or 2, characterized in that the containers with the cold-accumulating substance are placed at different levels above or below the sections of gravitational heat pipes containing evaporation zones. 6. The cooled base according to claim 5, characterized in that the container with the cold-accumulating substance is made in the form of a vessel with a neck having a hermetically sealed lid. 7. The cooled base according to any one of claims 1, 2, 4 and 6, characterized in that the cold storage substance is a liquid that hardens at a temperature of 0 - (- 3) ° C. 8. The cooled base according to claim 7, characterized in that the cold storage substance is water.