KR102248574B1 - Continuous operation hydrate slurry cooling system - Google Patents

Abstract

The present invention relates to a continuously operated-type hydrate slurry cooling system, capable of improving the cooling efficiency, which comprises: a plurality of storage tanks having a hydrate slurry stored therein; a dissociation unit for dissociating the hydrate slurry into water and carbon dioxide; a cooling line unit; a first pump provided in the cooling line unit; a generating unit for generating the hydrate slurry; a filling line unit; a second pump provided in the filling line unit; a valve unit provided in the cooling line unit and the filling line unit; and a control unit for controlling the opening and closing of the valve unit.

Description

Continuous operation hydrate slurry cooling system

The present invention relates to a continuous operation type hydrate slurry cooling system, and more particularly, by using a hydrate slurry filled in another storage tank while creating and filling hydrate using a plurality of storage tanks and a pair of generating and dissociating parts. It relates to a continuous operation type hydrate slurry cooling system for performing cooling.

Referring to Korean Patent Laid-Open No. 10-2011-0054279, gas hydrate is a special type of trapping compound, its appearance is a white solid similar to ice, but the crystal structure of the material and its physical properties are very different. In addition, in general, an empty space called a pupil is generated in a three-dimensional lattice structure formed by hydrogen bonds between water molecules under conditions of high pressure and low temperature, and low molecular weight gas molecules (methane, ethane, propane, carbon dioxide, nitrogen, oxygen Etc.) are physically captured and created.

These gas hydrates have potential properties that can be applied to various industrial fields, and thus, many studies have been conducted in recent years. It can be roughly divided into five areas, including securing fluid fluidity, recovery as an energy resource, climate change coping technology, gas transport and storage, and safety related to each of these fields.

In the gas hydrate production apparatus according to Korean Patent Publication No. 10-2011-0054279, water supplied from the water tank 11 is atomized using an ultrasonic atomizer 20, and the reactor 30 is made by gas hydrate generated gas. In the gas hydrate production apparatus 10 for producing gas hydrate by transferring to the cylinder, an atomization generation tank 21 of a cylindrical body and an ultrasonic vibrator 22 installed on the top of the atomization tank to atomize the supplied water and flow into the inside. ), and a transfer gas supply pipe 23 communicating with the side of the atomization tank to introduce gas hydrate generated gas as a transfer gas, and a mixed gas which is a transfer gas containing atomized water by communicating with the side of the atomization tank. An ultrasonic atomization apparatus 20 comprising a mixed gas transfer pipe 24 supplied to the upper part of the reaction tank, and a circulation pipe 25 communicating with the bottom of the atomization tank to transfer unatomized water back to the water tank; The reaction tank 31 of the cylinder and a cooling jacket 32 installed on the outer wall of the reaction tank to cool the reaction tank so that the gas hydrate generation reaction of the mixed gas supplied from the mixed gas inlet pipe connected to the upper part of the reaction tank occurs, and the A reactor composed of a gas hydrate discharge pipe 33 formed on the bottom of the reaction tank to discharge gas hydrate generated by the reaction, and an unreacted mixed gas discharge pipe 34 formed in the reaction tank to discharge unreacted mixed gas ( 30); consists of.

The gas hydrate produced by such a hydrate manufacturing apparatus will have excellent characteristics in terms of efficiency as a secondary fluid. However, the hydrate manufacturing apparatus gradually consumes the generated gas hydrate when cooling is performed using the generated gas hydrate, and when the exhausted gas hydrate cannot be simultaneously cooled while filling the exhausted gas hydrate, There was a problem in not performing cooling.

The present invention was created to solve the above problems, and a continuous operation that enables continuous operation because it is possible to simultaneously fill the hydrate slurry consumed when cooling the external object while cooling an external object using the generated hydrate slurry. It is an object of the present invention to provide a type hydrate slurry cooling system.

In order to achieve the above object, the present invention is provided to be spaced apart from a plurality of storage tanks in which the generated hydrate slurry is stored; A dissociation unit selectively receiving the hydrate slurry stored in the plurality of storage tanks and dissociating the supplied hydrate slurry into water and carbon dioxide; The plurality of storage tanks and the dissociation unit are selectively connected to perform cooling using hydrate slurry supplied to the dissociation unit, and the hydrate slurry stored in the plurality of storage tanks is selectively supplied to the dissociation unit, and then the dissociation unit A cooling line part selectively supplying the water and carbon dioxide dissociated in the plurality of storage tanks; A first pump provided in the cooling line unit and supplying the hydrate slurry stored in the plurality of storage tanks to the dissociation unit and supplying water and carbon dioxide dissociated from the dissociation unit to a plurality of storage tanks; A generator for generating a hydrate slurry by selectively receiving water and carbon dioxide from the plurality of storage tanks; The plurality of storage tanks and the generation unit are selectively connected to generate a hydrate slurry using water and carbon dioxide supplied to the generation unit, and water and carbon dioxide stored in the plurality of storage tanks are selectively supplied to the generation unit, and the A filling line unit selectively supplying the hydrate slurry generated by the generation unit to the plurality of storage tanks; A second pump provided in the filling line and supplying water and carbon dioxide stored in the plurality of storage tanks to the generation unit and supplying the hydrate slurry generated by the generation unit to the plurality of storage tanks; A valve part provided on the cooling line part and the filling line part and selectively opening and closing the connection of the plurality of storage tanks, the dissociation part, and the generation part; And it provides a continuous operation type hydrate slurry cooling system including a control unit for controlling the opening and closing of the valve unit.

The continuous operation type hydrate slurry cooling system according to the present invention is connected to the dissociation unit, cools an external object using the hydrate slurry supplied from the dissociation unit, and dissociated water and carbon dioxide while the hydrate slurry cools the external object. It may further include a load unit for supplying to the dissociation unit.

In addition, the continuous operation type hydrate slurry cooling system according to the present invention may further include a refrigeration unit connected to the generation unit and cooling the generation unit supplied with water and carbon dioxide to a set temperature to generate a hydrate slurry.

In the continuous operation type hydrate slurry cooling system according to the present invention, the plurality of storage tanks may be composed of a first storage tank and a second storage tank, and the first storage tank and the second storage tank are the cooling line part. And the filling line part, wherein the cooling line part comprises a first cooling line connecting the first storage tank and the second storage tank, and the first storage tank and the first storage tank spaced apart from the first cooling line. A second cooling line connecting the second storage tank and a third cooling line connecting the first cooling line and the second cooling line may be included. 1 pump may be provided.

The filling line part includes a first filling line connecting the first storage tank and the second storage tank, and a second filling line connecting the first storage tank and the second storage tank spaced apart from the first filling line. And, a third filling line connecting the first filling line and the second filling line, and the generator and the second pump may be provided on the third filling line.

The valve unit includes a first cooling valve provided on the first cooling line and the third cooling line to selectively open and close the first cooling line and the third cooling line, and the first storage on the second cooling line. A second cooling valve provided adjacent to the tank, a third cooling valve provided adjacent to the second storage tank on the second cooling line, and provided on the first filling line and the third filling line, the A first filling valve selectively opening and closing the first filling line and the third filling line, a second filling valve provided adjacent to the first storage tank on the second filling line, and the second filling line on the second filling line. It may include a third filling valve provided adjacent to the second storage tank.

The first cooling valve may be provided at a connection portion between the first cooling line and the third cooling line, and the first filling valve may be provided at a connection portion between the first filling line and the third filling line. In addition, the first cooling valve and the first filling valve may be a three-way valve.

In addition, the first cooling valve includes a first cooling opening/closing valve provided adjacent to the first storage tank on the first cooling line, and a second cooling valve provided adjacent to the second storage tank on the first cooling line. It may include an opening/closing valve and a third cooling opening/closing valve provided on the third cooling line, wherein the first filling valve is a first filling opening/closing provided on the first filling line adjacent to the first storage tank A valve, a second filling opening/closing valve provided on the first filling line adjacent to the second storage tank, and a third filling opening/closing valve on the third filling line.

The continuous operation type hydrate slurry cooling system according to the present invention can continuously generate hydrate slurry and use it to cool an external object, thereby improving cooling efficiency, and at the same time using a hydrate slurry that is exhausted when cooling an external object. After creation, it can be filled, enabling continuous operation.

1 is a block diagram showing a conventional gas hydrate manufacturing apparatus.
2 is a diagram schematically showing the configuration of a continuous operation type hydrate slurry cooling system according to an embodiment of the present invention.
FIG. 3 is a diagram illustrating a process of generating a hydrate slurry while performing cooling using the continuous operation type hydrate slurry cooling system shown in FIG. 2.
4 is a diagram illustrating a modified example of FIG. 3.
5 is a diagram schematically showing the configuration of a continuous operation type hydrate slurry cooling system to which a first cooling valve and a second filling valve according to another embodiment are applied.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors appropriately explain the concept of terms in order to explain their own invention in the best way. Based on the principle that it can be defined, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

2, the continuous operation type hydrate slurry cooling system 100 according to an embodiment of the present invention includes a plurality of storage tanks 1100, a dissociation unit 1200, a cooling line unit 1300, and a first A pump 1400, a generator 1500, a filling line unit 1600, a second camp 1700, a valve unit 1800, a control unit 1900, and a load unit 2000 and , It may further include a freezing unit (2100).

The plurality of storage tanks 1100 are provided to be spaced apart, and inside the plurality of storage tanks 1100, the hydrate slurry generated by the generation unit 1500 to be described later or the water and carbon dioxide from which the hydrate slurry is dissociated by the dissociation unit 1200 Is filled and stored.

In FIG. 1, the plurality of storage tanks 1100 are illustrated as being composed of a first storage tank 1120 and a second storage tank 1140, but the present invention is not limited thereto and may be formed of a plurality of storage tanks. In the embodiment of, a plurality of storage tanks 1100 will be described by dividing them into a first storage tank 1120 and a second storage tank 1140.

It is preferable that the inside of the first storage tank 1120 and the second storage tank 1140 are divided into upper and lower sides, respectively, and when the hydrate slurry generated to the upper side is supplied, dissociated water and carbon dioxide are discharged to the lower side. On the contrary, water and carbon dioxide may be supplied to the upper side, and hydrate slurry may be supplied to the lower side.

The first storage tank 1120 and the second storage tank 1140 are connected to the dissociation unit 1200 through a cooling line unit 1300 to be described later, and a generation unit ( 1500).

The dissociation unit 1200 receives the selection of the hydrate slurry stored in the first storage tank 1120 or the second storage tank 1140, and the water and carbon dioxide from which the hydrate slurry is dissociated are transferred to the first storage tank 1120 or It is supplied to the second storage tank 1140.

The dissociation unit 1200 is connected to the load unit 2000, and the load unit 2000 cools an external object using the hydrate slurry supplied from the dissociation unit 1200, and dissociated when cooling the external object. Water and carbon dioxide are supplied to the dissociation unit 1200. The load unit 2000 may be a heat exchanger generally used in a general refrigeration system, and the hydrate slurry is dissociated into water and carbon dioxide in the load unit 2000 to cool an external object by taking away heat from the surrounding area.

The first storage tank 1120, the second storage tank 1140, and the dissociation unit 1200 are selectively connected by a cooling line unit 1300 to use a hydrate slurry supplied to the dissociation unit 1200. Thus, the load unit 2000 performs cooling.

Hydrate slurry stored in the first storage tank 1120 or the second storage tank 1140 through the cooling line unit 1300 is selectively supplied to the dissociation unit 1200, and water from the dissociation unit 1200 And carbon dioxide are selectively supplied to the first storage tank 1120 or the second storage tank 1140.

The cooling line unit 1300 includes a first cooling line 1310, a second cooling line 1320, and a third cooling line 1330. The first cooling line 1310 connects the first storage tank 1120 and the second storage tank 1140 provided to be spaced apart, and the second cooling line 1320 is also the first storage tank 1120 ) And the second storage tank 1140, and the first cooling line 1310 and the second storage line 1320 are preferably provided to be spaced apart from each other.

The first cooling line 1310 and the second cooling line 1320 are connected by the third cooling line 1330, and the first storage tank 1120 or the third cooling line 1330 The hydrate slurry stored in the second storage tank 1140 is supplied to the dissociation unit 1200, and the water and carbon dioxide dissociated from the dissociation unit 1200 are supplied to the first storage tank 1120 or the second storage tank 1140. A first pump 1400 and the dissociation unit 1200 providing a power source supplied to a) are provided.

A portion of the third cooling line 1330 connected to the first cooling line 1310 and the first cooling line 1310 serves to supply a hydrate slurry to the dissociation unit 1200, and the second A part of the third cooling line 1330 connected to the cooling line 1320 and the second cooling line 1320 is used to transfer water and carbon dioxide to the first storage tank 1120 or the second storage tank 1140. It serves to supply.

The first storage tank 1120 and the second storage tank 1140 are also connected to a filling line unit 1600 provided to be spaced apart from the cooling line unit 1300, and a generation unit on the filling line unit 1600 1500 is provided.

The generation unit 1500 selectively receives water and carbon dioxide from the first storage tank 1120 or the second storage tank 1140 to generate a hydrate slurry. The generation unit 1500 is connected to the freezing unit 2100, and the freezing unit 2100 provides the generation unit 1500 so that the generation unit 1500 supplied with water and carbon dioxide can generate a hydrate slurry. It serves to cool down to a set temperature. The refrigeration unit 2100 may be a refrigeration system consisting of a general compressor, a condenser, an expander, and an evaporator, and if the generation unit 1500 can be cooled to a set temperature, a refrigeration system other than a general refrigeration system may be applied. I can.

The filling line unit 1600 selectively connects the first storage tank 1120 or the second storage tank 1140 and the generation unit 1500 to supply water and carbon dioxide to the generation unit 1500. After generating the hydrate slurry by using, the generated hydrate slurry is selectively supplied to the first storage tank 1120 or the second storage tank 1140.

The filling line part 1600 includes a first filling line 1610, a second filling line 1620, and a third filling line 1630. The first filling line 1610 connects the first storage tank 1120 and the second storage tank 1140, and the first filling line 1610 is adjacent to the first cooling line 1310. It is preferred to be arranged.

The second filling line 1620 is provided to be spaced apart from the first filling line 1610 to connect the first storage tank 1120 and the second storage tank 1140, and the third filling line 1630 ) Connects the first filling line 1610 and the second filling line 1620 provided to be spaced apart. On the third filling line 1630, water and carbon dioxide stored in the first storage tank 1120 or the second storage tank 1140 are supplied to the generation unit 1500 and generated by the generation unit 1500. A second pump 1700 providing a power source for supplying the hydrate slurry to the first storage tank 1120 or the second storage tank 1140 and the generation unit 1500 are provided.

A portion of the first filling line 1610 and the third filling line 1630 connected to the first filling line 1610 serves to supply water and carbon dioxide to the generation unit 1500, and A part of the third filling line 1630 connected to the second filling line 1620 and the second filling line 1620 is the first storage tank 1120 or the second storage tank 1140 as the generator. It serves to supply the hydrate slurry produced in (1500).

The cooling line part 1300 and the filling line part 1600 are provided with a valve part 1800 so that the first storage tank 1120 or the second storage tank 1140 and the dissociating part 1200 and the The generation unit 1500 is selectively connected.

The valve unit 1800 includes a first cooling valve 1810, a second cooling valve 1820, a third cooling valve 1830, a first filling valve 1840, and a second filling valve 1850. And, it includes a third filling valve (1860).

The first cooling valve 1810 is provided on the first cooling line 1310 and the third cooling line 1330 to selectively select the first cooling line 1810 and the third cooling line 1830. By opening and closing, the hydrate slurry stored in the first storage tank 1120 or the second storage tank 1140 is supplied to the dissociation unit 1200.

The first cooling valve 1810 is preferably provided at a connection portion between the first cooling line 1310 and the third cooling line 1330, and a three-way valve is used as the first cooling valve 1810. It is desirable.

A second cooling valve 1820 and a third cooling valve 1830 are provided on the second cooling line 1320, and the second cooling valve 1820 is provided on the second cooling line 1320 for the first storage. It is provided adjacent to the tank 1120, and the third cooling valve 1830 is provided adjacent to the second storage tank 1140.

The first filling valve 1840 is provided on the first filling line 1610 and the third filling line 1630 to selectively select the first filling line 1610 and the third filling line 1630. By opening and closing, water and carbon dioxide stored in the first storage tank 1120 or the second storage tank 1140 are supplied to the generation unit 1200.

The first filling valve 1840 is preferably provided at a connection portion between the first filling line 1610 and the third filling line 1630, and the first filling valve 1840 is the first cooling valve. It is preferable that a three-way valve is used in the same manner as in (1810).

A second filling valve 1850 and a third filling valve 1860 are provided on the second filling line 1620, and the second filling valve 1850 is the first storage on the second filling line 1620. It is provided adjacent to the tank 1120, and the third filling valve 1860 is provided adjacent to the second storage tank 1140.

Opening and closing of the valve unit 1800 is controlled by a control unit 1900, and the control unit 1900 controls the valve unit 1800 so that the first storage tank 1120 or the second storage tank 1140 The process of supplying the hydrate slurry stored in the dissociation unit 1200 to the dissociation unit 1200 and supplying the water and carbon dioxide dissociated in the dissociation unit 1200 to the first storage tank 1120 or the second storage tank 1140, and the first The water and carbon dioxide stored in the storage tank 1120 or the second storage tank 1140 are supplied to the generation unit 1500, and the generated hydrate slurry is supplied to the first storage tank 1120 or the second storage tank 1140. The process of supplying with) is as follows.

Referring to FIG. 3, while the first pump 1400 is operated by the control unit 1900, the hydrate slurry stored in the first storage tank 1120 is supplied to the first cooling line 1310. The control unit 1900 supplies the hydrate slurry to the dissociation unit 1200 through the third cooling line 1330 by adjusting the first cooling valve 1810 located in the first cooling line 1310. The hydrate slurry supplied to the dissociation unit 1200 is supplied to the load unit 2000 and is dissociated into water and carbon dioxide while cooling an external object, and then supplied to the dissociation unit 1200. The control unit 1900 opens the second cooling valve 1820 disposed on the second cooling passage 1320 and closes the third cooling valve 1830 to remove water and carbon dioxide from the dissociation unit 1200. 1 Cooling is performed by repeatedly performing the process of supplying to the storage tank 1120. The hydrate slurry stored in the first storage tank 1120 performs cooling while moving from A1 to A2, and the water and carbon dioxide from which the hydrate slurry is dissociated are supplied to the first storage tank 1120 while moving from A3 to A4. Cooling is performed while exhausting the hydrate slurry stored in the first storage tank 1120, and the dissociated water and carbon dioxide are stored in the first storage tank 1120.

At this time, the second storage tank 1140 provided to be spaced apart from the first storage tank 1120 cools the dissociated water and carbon dioxide to fill the hydrate slurry, and the control unit 1900 is the first pump 1700 Is operated to supply water and carbon dioxide stored in the second storage tank 1140 to the first filling line 1610. The control unit 1900 supplies water and carbon dioxide to the generation unit 1500 through the third filling line 1630 by adjusting the first filling valve 1840 located in the first filling line 1810. The water and carbon dioxide supplied to the generation unit 1500 are supplied to the refrigerating unit 2100 and cooled to generate a hydrate slurry and are supplied to the generation unit 1500. The control unit 1900 closes the second filling valve 1850 disposed on the second filling passage 1620 and opens the third filling valve 1860 to transfer the hydrate slurry of the generation unit 1500 to the second By repeatedly performing the process of supplying to the storage tank 1140, water and carbon dioxide stored in the second storage tank 1140 are used to generate a hydrate slurry. The water and carbon dioxide stored in the second storage tank 1140 move in the order of B1, B2, B3, and B4, thereby supplying the hydrate slurry to the second storage tank 1140 to provide the hydrate slurry of the second storage tank 1140. It will be filled.

The hydrate slurry stored in the first storage tank 1120 through the process shown in FIG. 3 is exhausted while performing cooling, and the hydrate slurry is filled in the first storage tank 1140, and the controller 1900 The first storage tank 1120 is filled with a hydrate slurry through the process of FIG. 4 and cooling is performed using the hydrate slurry stored in the second storage tank 1140.

The process shown in FIG. 4 is the opposite of the process shown in FIG. 3, and a detailed description thereof will be omitted.

5, the first cooling valve 1810 is not limited to using a three-way valve, and the first cooling valve 1810 includes a first cooling open/close valve 1811 and a second cooling open/close valve ( 1812), may include a third cooling opening and closing valve (1813).

The first cooling switch valve 1811 is provided on the first cooling line 1310 adjacent to the first storage tank 1120, and the second cooling switch valve 1812 is provided with the first cooling line 1310. ) Is disposed adjacent to the second storage tank 1140, and the third cooling opening/closing valve 1813 is provided on the third cooling line 1330.

The first filling valve 1840 is also not limited to using a three-way valve, and the first filling valve 1840 includes a first filling opening and closing valve 1841, a second filling opening and closing valve 1842, and a third cooling system. It includes an on-off valve 1843.

The first filling opening/closing valve 1841 is provided adjacent to the first storage tank 1120 on the first filling line 1610, and the second filling opening/closing valve 1842 is the first filling line 1610 ) Is disposed adjacent to the second storage tank 1140, and the third filling opening/closing valve 1843 is provided on the third filling line 1630.

The control unit 1900 includes the first cooling opening and closing valve 1811, the second cooling opening and closing valve 1812, the third cooling opening and closing valve 1813, the second cooling valve 1820, and the third cooling valve 1830. ) By selectively opening and closing the first storage tank 1120 or the second storage tank 1140 while performing cooling using the hydrate slurry stored in the first storage tank 1120 or the second storage tank 1140, the first filling opening and closing valve 1841, the second filling opening and closing valve 1842 ), the third cooling opening/closing valve 1843, the second filling valve 1850, and the third filling valve 1860 are selectively opened and closed to be stored in the first storage tank 1120 or the second storage tank 1140. Water and carbon dioxide are used to create and fill a hydrate slurry. When continuously generating and dissociating the hydrate slurry, it is preferable that the generation unit 1500 and the dissociation unit 1200 have a completely separated form.

Therefore, it is possible to continuously generate and use the hydrate slurry to cool an external object, thereby improving cooling efficiency, and the hydrate slurry that is exhausted when cooling an external object can be created and filled at the same time, making continuous operation possible. It becomes possible.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: Continuous operation type hydrate slurry cooling system
1100: storage tank 1120: first storage tank
1140: second storage tank 1200: dissociation unit
1300: cooling line part 1310: first cooling line
1320: second cooling line 1330: third cooling line
1400: first pump 1500: generating unit
1600: filling line unit 1610: first filling line
1620: 2nd filling line 1630: 3rd filling line
1700: second pump 1800: valve part
1810: first cooling valve 1820: second cooling valve
1830: third cooling valve 1840: first filling valve
1850: second filling valve 1860: third filling valve
1900: control unit 2000: load unit
2100: freezing unit

Claims (8)

A plurality of storage tanks provided spaced apart and storing the generated hydrate slurry;
A dissociation unit selectively receiving the hydrate slurry stored in the plurality of storage tanks and dissociating the supplied hydrate slurry into water and carbon dioxide;
The plurality of storage tanks and the dissociation unit are selectively connected to perform cooling using hydrate slurry supplied to the dissociation unit, and the hydrate slurry stored in the plurality of storage tanks is selectively supplied to the dissociation unit, and then the dissociation unit A cooling line part selectively supplying the water and carbon dioxide dissociated in the plurality of storage tanks;
A first pump provided in the cooling line unit and supplying the hydrate slurry stored in the plurality of storage tanks to the dissociation unit and supplying water and carbon dioxide dissociated from the dissociation unit to a plurality of storage tanks;
A generator for generating a hydrate slurry by selectively receiving water and carbon dioxide from the plurality of storage tanks;
The plurality of storage tanks and the generation unit are selectively connected to generate a hydrate slurry using water and carbon dioxide supplied to the generation unit, and water and carbon dioxide stored in the plurality of storage tanks are selectively supplied to the generation unit, and the A filling line unit selectively supplying the hydrate slurry generated by the generation unit to the plurality of storage tanks;
A second pump provided in the filling line and supplying water and carbon dioxide stored in the plurality of storage tanks to the generation unit and supplying the hydrate slurry generated by the generation unit to the plurality of storage tanks;
A valve part provided on the cooling line part and the filling line part and selectively opening and closing the connection of the plurality of storage tanks, the dissociation part, and the generation part; And
Continuous operation type hydrate slurry cooling system comprising a control unit for controlling the opening and closing of the valve unit.
The method according to claim 1
Continuously comprising a load unit connected to the dissociation unit, cooling an external object using the hydrate slurry supplied from the dissociation unit, and supplying the dissociated water and carbon dioxide to the dissociation unit while the hydrate slurry cools the external object Operational hydrate slurry cooling system.
The method according to claim 1,
A continuous operation type hydrate slurry cooling system further comprising a refrigeration unit connected to the generation unit and cooling the generation unit supplied with water and carbon dioxide to a set temperature to generate a hydrate slurry.
The method according to claim 1,
The plurality of storage tanks are composed of a first storage tank and a second storage tank, the first storage tank and the second storage tank are connected by the cooling line part and the filling line part,
The cooling line part,
A first cooling line connecting the first storage tank and the second storage tank,
A second cooling line connecting the first storage tank and the second storage tank to be spaced apart from the first cooling line,
And a third cooling line connecting the first cooling line and the second cooling line,
A continuous operation type hydrate slurry cooling system provided with the dissociation unit and the first pump on the third cooling line.
The method of claim 4,
The filling line part,
A first filling line connecting the first storage tank and the second storage tank,
A second filling line connecting the first storage tank and the second storage tank to be spaced apart from the first filling line,
And a third filling line connecting the first filling line and the second filling line,
A continuous operation type hydrate slurry cooling system provided with the generating unit and the second pump on the third filling line.
The method of claim 5,
The valve part,
A first cooling valve provided on the first cooling line and the third cooling line to selectively open and close the first cooling line and the third cooling line;
A second cooling valve provided adjacent to the first storage tank on the second cooling line,
A third cooling valve provided adjacent to the second storage tank on the second cooling line,
A first filling valve provided on the first filling line and the third filling line to selectively open and close the first filling line and the third filling line;
A second filling valve provided adjacent to the first storage tank on the second filling line,
Continuous operation type hydrate slurry cooling system comprising a third filling valve provided adjacent to the second storage tank on the second filling line.

The method of claim 6,
The first cooling valve is provided at a connection portion between the first cooling line and the third cooling line,
The first filling valve is provided at a connection portion between the first filling line and the third filling line,
The first cooling valve and the first filling valve is a continuous operation type hydrate slurry cooling system, characterized in that the three-way valve.

The method of claim 6,
The first cooling valve,
A first cooling open/close valve provided adjacent to the first storage tank on the first cooling line,
A second cooling opening/closing valve provided adjacent to the second storage tank on the first cooling line,
Including a third cooling opening and closing valve provided on the third cooling line,
The first filling valve,
A first filling opening/closing valve provided adjacent to the first storage tank on the first filling line,
A second filling opening/closing valve provided adjacent to the second storage tank on the first filling line,
Continuous operation type hydrate slurry cooling system comprising a third filling opening and closing valve provided on the third filling line.

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