RU2661167C2 - Heat setting of grounds - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to the field of construction in areas with complex engineering and geocryological conditions, namely, to heat setting of permafrost and loose grounds. Technical result is achieved by the fact that the heat setting of grounds of year-round action for cold accumulation in the bases of buildings and structures contains a steel pipe of the heat setting and an aluminium pipe of a condenser, wherein the heat setting condenser is made in the form of a vertical pipe consisting of a condenser body, a condenser cap and two condensers finned from the outside, a finned area is not less than 2.3 m², wherein the heat setting has an element for slinging in the upper part in the form of a mounting bracket.

EFFECT: technical result is an increase in the constructibility of the erection procedure of long-length heat settings, reduction of installation time, increase in the design reliability.

1 cl, 1 dwg

Description

The invention relates to the field of construction in areas with difficult engineering and geocryological conditions, namely thermostabilization of permafrost and soft soils.

It is known during the construction of capital structures, roads, overpasses, oil wells, tanks, etc. on permafrost soils, it is necessary to apply special measures to maintain the temperature regime of soils throughout the entire period of operation and to prevent softening of the bearing bases during thawing. The most effective method is the location at the base of the construction of plastic-frozen soil stabilizers, usually containing a pipe system filled with refrigerant and connected by a condenser part (for example: RF patent application No. 93045813, No. 94027968, No. 2002121575, No. 2006111380, Russian Patents No. 2384672, No. 2157872 .

Typically, an SPMG installation is carried out prior to the construction of structures: a foundation pit is prepared, a sand cushion is poured, thermal stabilizers are mounted, soil is poured and a layer of thermal insulation is installed (Journal “Foundations, foundations and soil mechanics, No. 6, 2007, pp. 24-28). After the construction is completed, monitoring the operation of the thermostabilizer and repairing individual parts is very difficult, which requires additional redundancy (Journal of Gas Industry, No. 9, 1991, p. 16-17). To improve the maintainability of thermostabilizers, it is proposed to place them inside the protective pipes with one plugged end, filled with a liquid with high thermal conductivity (RF patent No. 2157872). Protective pipes are placed under the soil and a layer of thermal insulation with a slope of 0-10 ° to the longitudinal axis of the base. The open end of the pipe is taken out of the boundaries of the soil dumping circuit. This design allows in case of leakage, deformation or other defects of the cooling pipes to remove them, to carry out maintenance and install back. However, in this case, the cost of the product significantly increases due to the use of protective tubes and special fluids.

To cool the soil at the base of the structures during the operational period, heat pipes of various designs are used (RF patent No. 2327940, RF patent for utility model No. 68108) installed in wells. To ensure the convenience of the manufacture, transportation and installation of heat pipes, their body has at least one insert made in the form of a bellows (RF patent for utility model No. 83831). The insert is usually provided with a rigid removable clip for fixing the relative position of the sections of the housing. A rigid ferrule may have a perforation to fill the space between it and the bellows with soil in order to reduce thermal resistance. Immersion of the heat pipe into the well is assumed to be sectional, by static indentation. This leads to large bending loads on the structure, which can lead to damage.

Close to the present invention is a method of eliminating the sediment of embankments on permafrost by freezing thawing soils with long-length thermosiphons (JSC Russian Railways, Federal State Unitary Enterprise VNIIZhT, “Technical Instructions for Eliminating Embankment Precipitation by Permafrost by Freezing Thawing Soils with Long-Term Thermosiphons”, M., 2007). This method involves drilling several deviated wells towards each other from opposite ends of the structure, after which cooling devices (thermosiphons) are immersed to the final depth of the well with a static pressing load. As already noted, this causes significant destructive loads on the structural elements of the cooling device.

Closest to the present invention is invention No. 2454506 C2 MPK E02D 3/115 (2006.01) “A cooling device for temperature stabilization of permafrost soils and a method for mounting such a device”. This invention is aimed at improving the manufacturability of the installation process of lengthy heat stabilizers, reducing installation time, increasing the reliability of the structure and replacing damaged areas while reducing the cost of installing the device.

The claimed technical result is achieved by the fact that the installation of a cooling device for temperature stabilization of permafrost soils includes:

- passing through the well;

- broaching in the direction opposite to the direction of penetration of the well of the heat stabilizer;

- installation of capacitors.

Thermostabilizer (long thermosiphon) contains condenser and evaporator pipes filled with refrigerant, connected by bellows sleeves (bellows). Each sleeve is reinforced with bandages. The condenser pipes are located at the edges of the thermostabilizer and the broaching is carried out to the position at which the condenser pipes will be located above the ground surface.

Condensers (heat exchangers) include condenser pipes with cooling elements installed on them (flanges, disks, fins, etc., or radiators of a different design). Typically, the heat exchanger is mounted by pressing disk flanges onto the condenser pipe. This method is most convenient in such climatic conditions. If necessary, welding and installation by means of bolted joints can be used. Capacitors of a different design may also be used within the scope of the present invention. The fact that the final installation of the capacitor is carried out after pulling the heat stabilizer through the well, allows the use of wells of smaller diameter and does not require large material and labor costs.

Installing capacitors on both sides of the thermostabilizer can improve the efficiency of the device. And the installation method allows the use of thermal stabilizers of much greater length and, as a result, significantly increase the cooling zone. One of the capacitors can be mounted at the factory, which simplifies the installation procedure in difficult climatic conditions. (Since pulling is used in place of the conventional indentation procedure of the temperature stabilizer according to the present invention, the risk of damaging the capacitor when installing the temperature stabilizer is reduced).

Thus, this invention improves the manufacturability of the installation process of lengthy thermostabilizers by changing the installation direction of the thermostabilizer; reduces the installation time of the device by reducing the number of operations and the ability to work on one side of the structure; increases the reliability and safety of installation; simplifies the procedure for replacing damaged areas. Due to the low cost of installation work and the possibility of their implementation during the operation of the facility, it is more cost-effective to replace failed thermal stabilizers by laying additional lines than dismantling and repairing them.

A disadvantage of the known technical solution is a complex structural solution and, as a consequence, a narrow field of application due to the limited piling depth and deep freezing of the soil in other cases, as well as a low efficiency due to the horizontal forced cooling system.

The objective of the present invention is to provide a rational, reliable soil thermal stabilizer that meets the high technological and structural requirements for maintaining the soil temperature regime throughout the entire period of operation, due to the thermal stabilizer's compliance with the architectural features of the structure.

Thermostabilizers are delivered to the installation site fully assembled, which do not require assembly on site. At the same time, the thermal stabilizer is manufactured in seismic regions (up to 9 points on the MSK-64 scale) with a service life and a service life of anticorrosive coating of 50 years. The temperature stabilizer has an anticorrosive coating (zinc), made in the factory.

The thermostabilizer is immersed immediately after drilling the well. The gap between the heat stabilizer and the wall of the well is filled with a soil solution with a moisture content of 0.5 or higher. Used soil drilled during the sinking of the well or clay-sand mixture.

The level of the bottom of the heat stabilizer and the level of the bottom of the well are determined during the installation of the heat stabilizer.

The invention is illustrated in Fig. one.

The thermal stabilizer consists of: a thermal stabilizer condenser 1, a condenser body 2, a condenser cap 3, a steel heat stabilizer pipe 4, an aluminum condenser pipe 5, a heat-stabilizer mounting bracket 6, a heat stabilizer body 7, a heat stabilizer tip 8, and an insulating heat stabilizer 9 insert.

The condenser of thermostabilizer 1 is made in the form of a vertical pipe - the body of the capacitor 2, consisting of a cap of the capacitor 3 and two finned capacitors on the outside, the fins are rolled by installing the aluminum condenser 5 pipe close to the weld.

The finning is highly efficient, the helical direction of the turns is arbitrary. On the surface of the fins, deformation on the turns of not more than 10 mm is allowed, coating of the surface of the aluminum pipe after knurling - chemical passivation in a solution of alkali and salt. The finning area is at least 2.43 m ² .

Effective cooling of the thermal stabilizer is achieved due to the large surface area of the fins.

The body of the thermostabilizer is allowed to be made of two or three parts welded on the installation of automatic welding of steel pipes MD (non-standard seam, welding by a rotating magnetically controlled arc).

The weld is tested for strength and tightness with air at an excess pressure of 6.0 MPa (60 kgf / cm ² ) under water.

Roll the condenser fins by installing the pipe with an aluminum cone close to the weld.

On the surface of the finning, deformation is allowed on coils with a depth of not more than 10 mm — linear, longitudinal and radial — screw, as well as up to seven coils from each end less than diameter 67. Coating the surface of an aluminum pipe after rolling — chemical passivation in a solution of alkali and salt. The area of the fins is not less than 2.3 m ² .

The temperature stabilizer has an element for slinging in the upper part in the form of a mounting bracket. Slinging is carried out using a textile sling in the form of a loop, with a lifting capacity of 0.5 t.

Thermostabilizers have an external anti-corrosion zinc coating, made in the factory.

Climatic conditions for the installation of thermal stabilizers:

- temperature not lower than minus 40 ° C;

- relative air humidity from 25 to 75%;

- atmospheric pressure 84.0-106.7 kPa (630-800 mm Hg).

The place for the installation of thermostabilizers must meet the following conditions:

- have sufficient illumination, not less than 200 lux;

- Must be equipped with lifting gear.

The gap between the heat stabilizer and the wall of the well is filled with a soil solution with a moisture content of 0.5 or higher. Used soil drilled during the sinking of the well, or clay-sand mixture.

Thermal stabilization of the heat stabilizer 9 is carried out in the seasonal thawing zone.

Steel for steel pipes of the heat stabilizer is adapted to the conditions of the north and has an anti-corrosion zinc coating. The thermal stabilizer is lightweight due to its small diameter, while maintaining a wide radius of soil freezing.

Thermostabilizers are delivered to the installation site fully assembled, which do not require assembly on site. At the same time, the thermal stabilizer is manufactured in seismic regions (up to 9 points on the MSK-64 scale) with a service life of anticorrosive coating of 50 years. The temperature stabilizer has an anticorrosive coating (zinc), made in the factory.

Claims (1)

Thermostabilizer of year-round soils for accumulating cold in the foundations of buildings and structures, containing a steel tube of a heat stabilizer and an aluminum condenser pipe, characterized in that the condenser of the thermostabilizer is made in the form of a vertical pipe consisting of a condenser body, a condenser cap and two ribbed capacitors from the outside, the area the fins of which are not less than 2.3 m ² , while the thermostabilizer has an element for slinging in the upper part in the form of a mounting bracket.

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