SU846639A1 - Apparatus for accumulating cold in foundations of structures - Google Patents

Description

(54) DEVICE FOR ACCUMULATING A COLD IN THE FOUNDATION OF CONSTRUCTIONS The invention relates to the implementation of devices for accumulating cold at the base of structures used in their construction on permafrost. A device for accumulating cold at the base of structures is known, which includes a tubular body with a bottom installed partially installed in the ground and filled with liquid hygiene agent. n cover D-j. The efficiency of this device is not high enough due to the fact that in the warm period of the year it has a warm effect on the ground, as well as due to the low rate of natural circulation of the refrigerant. It is also known a device for accumulating cold at the base of the structures, comprising a partially installed 9 soil and a tubular body filled with liquid refrigerant with a bottom, a lid and a transverse annular diaphragm and a float which is filled with water in a coolant freely immersed Zj. In the cold period of the year, the water in the tank turns into ice, increases in volume, and the float floats freely in the upper part of the hull; when the outside temperature rises, the ice in the tank melts, the capacity decreases in volume, and the float sinks down to rest on the diaphragm. As a result, the cavity of the housing is blocked by a float, and the circulation of the refrigerant stops. This device prevents it from warming up, but during the cold period of the year the coolant is circulated through its natural convention and has a low speed. The closest to the proposed invention is a device for cold accumulation in the base of the structure: including the valve partially installed in the gruel and filled with a liquid refrigerant: a tubular body with a bottom and a lid and a coolant placed inside the body to enhance the coolant heating in the form of a pipe On the inner side of the outer side surface there are helical blades that are rotated by means of a shaft connected to the wind of the GZZ engine. In this device, the rate of circulation of the refrigerant is higher than its natural,

Convention, which increases the efficiency of the device. However, the operation of the device for enhancing refrigerant circulation depends on the wind pressure, i.e. weather conditions, which adversely affects the reliability of the device.

The purpose of the invention is to increase the reliability of the device.

This goal is achieved by the fact that an electronic device for accumulating cold at the base of structures, including a tubular body partially installed in the ground and filled with liquid refrigerant, with a shower and a lid and a device for enhancing coolant circulation placed in the body. the latter is made in the form of an airtight container with deforming walls, freely immersed in a refrigerant and filled with a working agent in the form of a boiling liquid or gas hydrate, or equipped with a metal rod, the ends of which are attached to its opposite walls. In order to more evenly distribute the working element in the vessel with deforming walls, the latter is provided with plates dividing it into sections, with the sections communicating with each other and the working agent is filled with each section.

Increasing the degree of refrigerant circulation enhancement can be achieved by making a container with deforming walls, filled with a working agent with plates dividing it into sections, the sections communicating with each other, and filling agent with each section, or making the device additionally with containers with rigid stacks, placed in a row manner over a container with deforming walls, filled with a working carrier, and communicated with it and each other by means of a heat-insulated pipe, each capacitor the hard walls are filled with a working agent, or the device is additionally equipped with a heat-insulated glass filled with the working agent, and with a heat exchanger with a heat-insulating sleeve surrounding it, and the upper end extends beyond the container with deforming walls and is enveloped in a heat insulating sleeve at the exit portion. In this case, when performing a device with the indicated additional features, it is advisable that inside the case gravitational or thermal relays would be attached to its lid and bottom.

FIG. 1 shows the device described, the option of filling a container with deforming walls with a working agent, a longitudinal section; in fig. 2 - the same, an embodiment of a container with a metal rod, a longitudinal section; in fig. 3 is the same, an embodiment of a container with plates, a longitudinal section; in fig. 4 - the same, an embodiment of the device additionally with containers with rigid walls, a longitudinal section; in fig. 5 shows the described device, an embodiment of the device additionally with a heat-insulated glass and a heat exchanger.

The described cold storage device includes partially installed in the ground 1 and filled with liquid refrigerant 2, such as kerosene, a tubular body 3 with the bottom 4 and a lid 5. Inside the case in refrigerant 2 there is a container b with deforming walls, for example, a bellows with metal walls. Siphon 6 is filled with a working agent 7 in the form of a light boiling liquid or gas hydrate or is equipped with a rod 8 of metal with a high linear expansion coefficient, for example cadmium, attached at its ends to the end face.

0 walls of the bellows. Propane hydrate can be used as a gas hydrate, which is obtained as a slurry from propane gas and an aqueous solution of n-propyl alcohol, where n-propyl alcohol acts as an activator of the formation and dissociation of the hydrate.

With an increase in temperature in a low-boiling liquid, its boiling takes place and the transition of the liquid phase to the gas phase and in the gas hydrate its dissociation and the transition of the solid phase to the liquid and gas phases.

The weight of the filled bellows is selected so that at the calculated cooling temperature of the soil the bellows 6 freely floats in the refrigerant in the upper part of the housing 3. At the same time, the gas phase of the working agent above its liquid phase is in equilibrium.

When the outside temperature decreases, causing the upper layers of the refrigerant to drop, the gaseous phases of the working agent change to liquid

5 or solid, with the result that the gas pressure in the bellows decreases, the walls of the bellows contract, and the bellows itself decreases in volume. When performing bellows with a rod

0 8 a decrease in the volume of the bellows is achieved due to the shortening of the rod and the approach of the end walls of the bellows.

Claims (5)

Reducing the volume of the bellows at 5 leads to a loss of buoyancy and bellows. moves to the bottom of the hull, displacing the warmer refrigerant 2 into the upper part of the hull, and cooling the surrounding array of soil. In the process of heat exchange between the bellows 6 and the cooled soil, the temperature of the working agent or metal rod decreases, the liquid and solid phase of the working agent passes into the gas, increasing the gas pressure in the bellows, and the metal rod 8 lengthens. This leads to stretching of the bellows walls and an increase in its volume. Increasing the volume of the bellows 6 increases its buoyancy and the bellows pops up in the refrigerant 2 to the upper part of the body, displacing the cold refrigerant from the upper part of the body to the lower. The process of transferring one phase of the working agent to another can be accelerated by placing inside the bellows.6 plates 9 that divide the cavity of the bellows into sections communicating with each other or by placing over the bellows a system of communicating capacitors 10 which are communicating with each other and communicating with the bellows 6. Communication of containers 10 of the bellows 6 is carried out using a heat-insulated pipe 11. In this case, the layer of the working agent in the liquid or solid phase is placed on each plate 9 or at the bottom of each section 10, resulting in an active surface; dissociation of the working agent and the intensity of the formation of its gas phase increases. The process of transition of one phase of the agent to another can be accelerated by placing the insulated cup 12 inside the bellows 6, filled with the working agent. The radiator-heat exchanger 13 is installed in the cup so that its lower end is placed in the cup, and the upper one is removed from the bellows and is placed above it. In the exit section of the bellows the radiator heat exchanger is covered by the heat insulating sleeve 14. The housing 3 is filled with refrigerant 2 below the upper end of the thermal insulator hub bushing 14. In this case, at the beginning of the winter period, when atmospheric air is oxidized; to negative temperatures, the gaseous medium in the housing 3, located above the surface of the refrigerant 2, cools faster than the refrigerant 2. The cold from the gaseous medium through the heat exchanger 13 is transferred to the working agent 7 filling the insulated cup 12. The working agent 7 is cooled before the refrigerant. 2 and the transition process of the initial liquid or solid phase of the working agent, respectively, in the gas or liquid. and the gas phase is accelerated. Accelerating the process of transferring the working agent on one phase to another increases the speed of movement of the bellows and, consequently, the intensity of movement of refrigerants in the case. When the device is made with containers 10 or a heat-insulated glass 12 and heat exchanger 13, the housing may not be fully filled with gas in the upper part of the housing, and gravity or thermal relays 15 and 16 (for example, based on magnets or bimetallic plates) are installed on the ends of the housing which are included in the adjustable adhesion force with the upper tank 10 or the heat exchanger 13 and with the bottom of the bellows 6 .; The relay 15 holds the tank system 10 or the heat exchanger 13 in the upper part of the body until the required reduction of the buoyancy force acting on the bellows 6 from the side of the exhaust plug 2 and after reaching the buoyancy force of a certain size of the capacity system - the bellows or heat exchanger - the bellows comes out of the clutch with the relay 10, moves down and engages with the relay 16 until the buoyant force is increased by the required amount. In so doing, relays 15 and 16 accelerate the movement of the bellows capacity systems and the bellows heat exchanger systems. Thus, the presence of a bellows body moving in the refrigerant, allows to increase the intensity of the refrigerant convection and thereby increase the period of the cooling effect of the device and increase the efficiency of cold storage at the base of the structure. Claim 1. Device for accumulating cold at the base of structures, including a tubular body partially installed in the ground and filled with liquid refrigerant, with a bottom and a lid and accommodating a device for enhancing refrigerant circulation inside the body, in order to increase the reliability of the device , a device for enhancing the circulation of the refrigerant is made in the form of an airtight container with deforming walls, freely immersed in the refrigerant and filled with a working gas in the form of light with a liquid or gas hydrate, or provided with a metal rod, the ends of which are attached to its outer walls. 2. A device according to claim 1, characterized in that the container with deforming walls, filled with a working agent, is provided with plates dividing it into sections, the sections communicating with each other, and each section is filled with a working agent. 3. A device according to Claim 1, characterized in that it is provided with containers with rigid walls that are uniformly razmated over a container with deforming walls filled with a working agent, and communicated with it and with each other by means of a heat-insulated pipe. walls filled with a working agent. 4. The device according to Claim 1, characterized in that it is provided with a heat-insulated glass filled with a working agent and a heat exchanger with a heat-insulating sleeve partially covering it, and X /one insulated glass installed. in the vessel with deforming walls, and the heat exchanger with its lower end is placed in the glass, the upper end is brought out of the container with deforming walls and enveloped in a heat insulating sleeve at the exit section. 5. A device according to claims 3, 3 or 4, characterized in that inside the case gravitational or thermal relays are attached to its lid and bottom. Sources of information taken into account in the examination 1.Gapeev S.I. Strengthening frozen bases by cooling. L. Stroyizdat, 1969, p. 18-20. 2. Authors certificate of the USSR. 720101, cl. E 02 D 3/12, 1977.. 3. USSR author's certificate 0578401, class E 02 D 3/12, 1976 (prototype) / 7 /, -. :: i // i nA - - / V // C6N // X V V X ui.i W l y / ,, IS Figm fj W 12 . , / Put.S