SU543357A4 - Multi-layer thermal insulation of underground structures - Google Patents

Description

shown in FIG. 2, a thermocouple 7 is located between the ground 3 and the thermal insulating layer 4. In the embodiment shown in FIG. 3, the heat dissipating element 2 is surrounded by a heat insulating layer 8. Next, a heat dissipating element 9 is placed. Thermo element 10 is located between the heat removing element 9 and the ground 3. equipped with radiators 12.

The embodiment of the insulation in FIG. 1 includes a protective insulation layer 4 around the heat sink element 2. This variant, as well as the following variants in FIG. 2 and 3 are particularly suitable for permafrost regions, where heat can destroy the permafrost support. A special permafrost region, the structure of which is adapted to FIG. 1 is the one where the unusually cold extended winter months are. The heat removal element 2 in this case makes it possible to save the oil at a low temperature by discharging the excess heat resulting from friction flow. With insulating layer 4, the interfacial point of freezing is created between pipeline 1 and the permafrost soil in such a way that no permafrost is significant. Again, this is applicable only where freezing conditions are extraordinary, and the permafrost soil therefore has a high degree of heat absorption to absorb any heat flux through the insulation.

Where winter is not so severe, so the degree of heat absorption by the permafrost MeHbuie soil, which is necessary for the variant in FIG. 1, in this case the variant shown in FIG. 2. The functions of the comparable elements of this variant are similar to the variant of FIG. 1. In addition, a thermocouple 7 is used to absorb the excess heat that can pass through the insulation layer 4. The thermocouple 7 accumulates this heat until the winter period ends. Then this heat is transferred through the permafrost soil to the atmosphere. Thermal retraction acts to remove excess heat from the liquid.

in order to keep it at the required temperature.

The thermal retraction function, as shown in FIG. 3 serves to remove excess heat from the pipe, which may form from the friction of the fluid flow, so as to maintain the heated product at the required temperature. The thermal retraction operates all year round to remove heat from the liquid, and the heat removal element 9 acts only during the winter months in order to regenerate the thermoelement 10. In the winter, the thermoelement 10 therefore dumps its excess heat into the heat-active soil layer lying above and

thus, to the atmosphere through the clamps 12 of the heat dissipating element 9 so that the amount of excess heat discharged into the adjacent permafrost soil is within its power to obtain heat without

that neither. Because of this difference in action is better.

just keep thermal outlets (9 and 2)

isolated one from the other by

extension between clamps (6 and 12).

Thus, the invention can relieve excess heat from the heated fluid in the pipeline and simultaneously protect the permafrost soil.

Claims (3)

1. Multilayer thermal insulation of underground structures according to patent no. 520938, characterized in that, in order to reduce and stabilize the heat flow between the structure and the ground, a heat removal element is made in the form of shells, and the space between the shells is filled liquid with a freezing point of 0 ° C or less. 2. Heat insulation according to claim 1, characterized in that between the shells there are reinforcing elements that do not interfere with the flow of the liquid. 3. Thermal insulation on PP. 1 and 2, characterized in that the heat-removing element is provided with radiators for dissipating heat into the environment.  - ig.2