RU137868U1 - CONTAINER FOR STORAGE AND TRANSPORTATION OF LIQUID CRYOPRODUCTS - Google Patents

Abstract

1. A container for storing and transporting liquid cryogenic products, characterized in that it contains an external sealed evacuated shell, on the inner surfaces of the bottom of which and its side walls there are permanent magnet systems, and a sealed vessel filled with liquid cryoproduct placed in its cavity on the outer surfaces the bottom of which and its side walls are installed opposite to the permanent magnet systems of the outer shell of the system of superconducting electromagnets, moreover, on the upper end at least two gas and liquid phases of the cryoproduct inlet-outlet are installed on the surface of the sealed vessel filled with liquid cryoproduct, and a gas and liquid phase inlet-outlet hatch of the cryoproduct is installed on the upper end surface of the outer sealed evacuated shell. 2. A container according to claim 1, characterized in that an overpressure relief valve and an electromagnetic field intensity control unit are installed on the upper end surface of the sealed vessel filled with liquid cryoproduct. The container according to claim 1, characterized in that it is provided with a pressure regulation unit for vacuum pressure located in the cavity of the sealed evacuated shell. The container according to claim 1, characterized in that an additional system of superconducting electromagnets is installed on the upper end surface of the sealed vessel, and an additional system of permanent magnets is installed on the inner side of the upper end surface of the sealed shell.

Description

The utility model relates to the field of transport engineering, in particular to devices for storage and transportation of liquid cryogenic products, including liquefied natural gas.

A known tank for storing and transporting explosive cryogenic liquid, consisting of a casing, an inner vessel with heat insulation and nozzles for filling and emptying liquid, a floating cover with holes and a remote condenser of liquid vapor, while the floating cover has a porous plate with pore sizes less than critical flame-extinguishing channels, and the holes in the cover are made in the form of conical chambers in which spherical valves are located (RU 2315901, 06/10/2004).

The drawback of the reservoir design is the presence of many rigid elements connecting the inner vessel to the casing: supports of the inner vessel, pipelines, which are the bridges of the transfer of thermal energy from the external environment to the cryogenic liquid. Due to this, the efficiency of thermal insulation of the inner vessel is reduced, as a result of which the evaporation of the cryogenic liquid is intensified and the presence of a continuously working vapor condenser is necessary, which helps to increase the material consumption of the structure, increase the cost and complicate the operation of the tank.

A known tank for transporting liquefied natural gas, containing a main shell mounted on an automobile or railway platform, inside which there is a vessel for transporting liquefied natural gas, and the space between the main shell and the vessel is filled with insulating material, while between the main shell and the vessel for transporting liquefied natural gas natural gas installed and fixed an additional shell, and the space between the main and additional shell is used to transport liquid bones having a boiling point above ambient temperature and a melting point comparable with the boiling point of the transported cryogenic liquid, the space between the additional shell and the vessel is filled with insulating material (RU 115309, 07/21/2011).

The disadvantages of the known solution are the significant complication of the design and operation due to the presence of an intermediate tank in which it is necessary to contain a liquid having a melting point comparable to the boiling point of the transported cryogenic liquid, and the presence of a large number of rigid elements — pipelines, valves, support nodes — connecting shells tanks and which are the bridges of heat transfer between the shells, which reduces the efficiency of thermal insulation of the transported cryogenic liquid.

Of the known technical solutions, the closest to the proposed one is a container tank for liquid cryogenic products, containing a frame, thermal insulation, a cylindrical boiler with two power belts, each of which is equipped with two devices for compensating for temperature deformations, made in the form of a dovetail movable pair, one of the parts of which, on the one hand, through heat-insulating gaskets is rigidly connected to the bracket of the boiler power belt, and on the other, to the body of the hydraulic cylinder, the other part of the movable pair it is tightly connected with the frame of the frame and interacts with the piston of the hydraulic cylinder, while the bypass piston has two bypass valves - one direct and one reverse, and devices for compensating for thermal deformations located on one of the power zones are installed by the axes of its movement across the axis of the boiler, and other devices located in the second power zone, are installed by the axes of their movement along the diagonals of the supporting half-planes of the boiler, and the frame is equipped with brackets with heat-insulating gaskets, the grooves of which interact with the center shining protrusions of power belts (RU 2208568, 06/22/2001).

The known solution provides a reduction in heat inflows through the power connections of the boiler with the container by reducing the number of these power connections, and also provides compensation for temperature deformations of the boiler and container in the nodes of their communication and a more uniform distribution of external loads on the power connections.

The disadvantage of this solution is the presence of rigid (power) connections between the boiler and the container, which are the bridges of heat transfer from the external environment to the liquid cryoproduct and thereby reduce the efficiency of thermal insulation of the liquid cryoproduct, which, in the absence of additional cooling devices, significantly reduces the permissible storage / transportation period liquid cryoproduct in a tank container.

The objective of this utility model is to increase the efficiency of thermal insulation of a vessel with liquid cryoproduct.

This object is achieved in that the container for storing and transporting liquid cryogenic products contains an external sealed evacuated shell, on the inner surfaces of the bottom of which and its side walls there are permanent magnet systems, and a sealed vessel placed in its cavity filled with liquid cryoproduct, on the outer surfaces of the bottom of which and its side walls are installed opposite to the permanent magnet systems of the outer shell of the system of superconducting electromagnets, and on the upper at least two fittings for the inlet-outlet of the gas and liquid phases of the cryoproduct are installed on the front surface of the sealed vessel filled with liquid cryoproduct, and a hatch for the inlet-outlet of the gas and liquid phases of the cryoproduct is installed on the upper end surface of the outer sealed evacuated shell.

In preferred embodiments:

- an overpressure relief valve and an electromagnetic field intensity control unit are installed on the upper end surface of the sealed vessel;

- the container is equipped with a vacuum pressure control unit.

- an additional system of superconducting electromagnets is installed on the upper end surface of the sealed vessel, and an additional system of permanent magnets is installed on the inner side of the upper end surface of the sealed shell.

Achievable technical result is to reduce the intensity of heat transfer between the cryoproduct and the environment to the lowest possible level due to the magnetic suspension of the vessel with the cryoproduct in the outer shell.

The essence of the proposed utility model is illustrated by the drawing, which shows a diagram of the proposed container for storage and transportation of liquid cryogenic products.

The container for storing and transporting cryoproducts contains an external sealed evacuated shell 1, on the inner surfaces of the bottom of which and its side walls there are permanent magnet systems 2, 3, and a sealed vessel 4 filled in its cavity, filled with liquid cryoproduct, on the outer surfaces of the bottom of which and its the side walls are installed opposite to the permanent magnet systems of the outer shell of the system 5, 6 of superconducting electromagnets, and on the upper end surface of the sealed vessel filled with liquid cryoproduct, at least two fittings 7 for the inlet-outlet of the gas and liquid phases of the cryoproduct are installed, and a hatch 8 for the inlet-outlet of the gas and liquid phases of the cryoproduct is installed on the upper end surface of the outer sealed evacuated shell. On the upper end surface of the sealed vessel filled with liquid cryoproduct, an overpressure relief valve 9 and an electromagnetic field intensity control unit 10 are installed. The container is equipped with a rarefaction pressure control unit 11 located in the cavity of the sealed evacuated shell and an emergency valve 12 of the sealed shell located on the upper end surface of the sealed shell. An additional system 13 of superconducting electromagnets can be installed on the upper end surface of the sealed vessel, and an additional system of 14 permanent magnets is installed on the inside of the upper end surface of the sealed shell.

A container for storing and transporting cryoproducts operates as follows.

Stage 1. Filling.

At the first stage, the technical condition of the main elements of the container is checked, after which, with the hatch 8 of the gas and liquid phases of the cryoproduct open, external communications are connected (not shown in the drawing) and, if necessary, preliminary cooling of the sealed vessel 4 and communications is carried out by gradual supplying a small amount of liquid cryoproduct through the nozzle 7 for the inlet-outlet of the gas and liquid phases of the cryoproduct into the internal cavity of the sealed vessel 4 until the rate is reached rature winding system 5 superconductive electromagnets situated on the bottom of the inner vessel and the temperature of the side systems windings of superconducting electromagnets 6 values at which the winding material acquires the property of superconductivity. Excessive cryogenic product vapors arising from the transfer of heat from the walls of the sealed vessel 4 to the liquid cryogenic product can be removed through the nozzle 7 for the inlet-outlet gas and liquid phases of the cryogenic product. After cooling the windings, external communications (not shown) are disconnected from the fittings 7 for inlet-outlet of the gas and liquid phases of the cryoproduct and the vessel 4 is sealed. Next, by connecting an external source to the electromagnetic field intensity control unit 10, current is induced in the system windings 5 superconducting electromagnets located on the bottom of the inner vessel, as well as in the windings of the side systems 6 of superconducting electromagnets until they reach the magnitude of the current go value. At the same time, magnetic fields are induced around the windings of the superconducting electromagnets, which interact with the magnetic fields of the permanent magnets of the system of 2 permanent magnets located on the bottom of the sealed shell, and of the side systems 6 of permanent magnets, and a repulsive force arises, which compensates for the weight of the sealed vessel 4, as a result of which it detaches from the surface of the system of 2 permanent magnets located on the bottom of the sealed shell, at a distance h and fixes its position in space in suspension, and, starting from the moment of inducing magnetic fields, during the filling, storage, transportation and emptying of the container, the current magnitude in the windings of superconducting electromagnets is automatically controlled by the electromagnetic field intensity control unit 10. Upon reaching the fixed position of the sealed vessel 4 in space, the external communications are re-connected with the fittings 7 for the inlet-outlet of the gas and liquid phases of the cryoproduct and the sealed vessel 4 is filled with liquid cryoproduct in the quantity necessary for storage and / or transportation, after which the external communications are disconnected and sealing the vessel 4. Immediately after disconnecting the external communications and sealing the vessel 4, the outer shell 1 is sealed I am closing the hatch 8 of the inlet-outlet gas and liquid phases of the cryoproduct. Next, the external vacuum line is connected to the rarefaction pressure control unit 11 and the vapor-air medium is pumped out from the space of the container’s internal cavity between the external sealed shell 1 and the sealed vessel 4 until the required vacuum depth is reached, after which the external vacuum technological line is disconnected without breaking the outer shell 1 .

2 stage. Storage and / or transportation.

During storage and / or transportation, the container is installed in the required position so that its stable position relative to the external support elements is maintained and its vertical orientation is respected. After the container is installed in the storage and / or transportation position, depending on the availability of technological capabilities, environmental conditions and the duration of storage and / or transportation, the following is carried out: connecting an external power source to the electromagnetic field intensity control unit 10, connecting an external technological vacuum control unit 11 vacuum lines, connecting an external device for vapor condensation (not shown in the drawing) of a liquid cryoproduct to a piece 7 am inlet-outlet of cryogenic gas and liquid phases in continuous or batch mode and external grounding conductive elements of the container (not shown in the drawing).

When the magnitude of the current in the windings of the system 5 of superconducting electromagnets located on the bottom of the inner vessel, or side systems 6 of superconducting electromagnets from the acceptable values or when the clearance h decreases below the minimum acceptable value, the corresponding parameters are adjusted and stabilized automatically by the intensity control unit 10 electromagnetic fields.

When the pressure in the space of the inner cavity of the container between the outer sealed shell 1 and the sealed vessel 4 is increased above the maximum permissible value due to depressurization of the outer shell 1 or vessel 4, if there is technological capability, the external vacuum line is pumped to the rarefaction pressure control unit 11 and pumped out vapor-gas medium from the inner cavity of the container between the outer sealed shell 1 and the sealed vessel 4 until the required vacuum depth is reached, after which the external vacuum processing line (not shown in the drawing) is disconnected without violating the tightness of the outer shell 1.

In case of emergency excess of the vapor pressure of the cryoproduct in the sealed vessel 4 of critical value, the overpressure relief valve 9 and the emergency valve 12 of the hermetic shell automatically open, as a result of which the excessive amount of vapor of the cryoproduct is removed into the environment until the vapor pressure in the sealed vessel 4 decreases to a value below the critical values, after which the overpressure relief valve 9 and the emergency valve 12 of the sealed enclosure are closed.

If it is possible to connect an external device for the condensation of the cryoproduct to the fittings 7 for inlet-outlet of the gas and liquid phases of the cryoproduct, it can be continuously or periodically during storage and / or transportation, depending on the temperature of the liquid cryoproduct or the vapor pressure of the cryoproduct in an airtight vessel 4, in manual or automatic mode, the selection of vapors from the inner vessel 4, their cooling in an external condensation device to a temperature below the boiling point and return to as a liquid cryoproduct into a sealed vessel 4, as a result of which the temperature of the liquid cryoproduct and the vapor pressure of the cryoproduct in a sealed vessel 4 can be reduced.

Permanent or periodic connection of external communications with fittings 7 for the inlet-outlet of the gas and liquid phases of the cryoproduct during storage or transportation can be performed without violating the tightness of the outer shell 1 by introducing the conductive tips of the external channels for the inlet-outlet of the gas and liquid phases of the cryoproduct (not shown ) into the cavity of the outer shell 1 through the hatch 8 of the inlet-outlet of the gas and liquid phases of the cryoproduct and connecting the tips to the fittings 7 for inlet-outlet of the gas and liquid phases cryoproduct so that, by means of sealing and valve devices, the inserted tips form temporary tight lock chambers with fittings 7 for the inlet and outlet of the gas and liquid cryoproducts, directly through which the inlet and outlet of the gas and liquid phases of the cryoproduct can be carried out without contact with the vacuum space of the internal the cavity of the container between the outer sealed shell 1 and the sealed vessel 4.

3 stage. Emptying

When emptying the container, first the nozzles 7 for the inlet-outlet of the gas and liquid phases of the cryoproduct are connected to external communications, through which the liquid cryoproduct will be pumped out, after which the liquid cryoproduct is pumped through the nozzle 7 for the inlet-outlet of the gas and liquid phases of the cryoproduct automatic adjustment of the gap h between the upper end surface of the system of 2 permanent magnets located on the bottom of the sealed shell, and the bottom s end surface of superconducting electromagnets system located on the bottom of the inner vessel portion 10 regulate the intensity of electromagnetic fields. When reducing the amount of liquid cryoproduct in the sealed vessel 4, as a result of pumping to the minimum acceptable value, external communications are disconnected from the inlet-outlet fittings 7 of the gas and liquid phases of the cryoproduct. If it is necessary to completely empty the sealed vessel 4, the block 10 controlling the intensity of the electromagnetic fields, the currents in the windings of the electromagnets are reduced to zero.

Claims (4)

1. A container for storing and transporting liquid cryogenic products, characterized in that it contains an external sealed evacuated shell, on the inner surfaces of the bottom of which and its side walls there are permanent magnet systems, and a sealed vessel filled with liquid cryoproduct placed in its cavity on the outer surfaces the bottom of which and its side walls are installed opposite to the permanent magnet systems of the outer shell of the system of superconducting electromagnets, moreover, on the upper end at least two gas and liquid phases of the cryoproduct inlet-outlet are installed on the surface of the sealed vessel filled with liquid cryoproduct, and the gas and liquid phases of the cryoproduct inlet-outlet are installed on the upper end surface of the outer sealed evacuated shell. 2. The container according to claim 1, characterized in that on the upper end surface of the sealed vessel filled with liquid cryoproduct, an overpressure relief valve and an electromagnetic field intensity control unit are installed. 3. The container according to claim 1, characterized in that it is equipped with a vacuum pressure control unit located in the cavity of the sealed evacuated shell. 4. The container according to claim 1, characterized in that an additional system of superconducting electromagnets is installed on the upper end surface of the sealed vessel, and an additional system of permanent magnets is installed on the inside of the upper end surface of the sealed shell.

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