KR20150083597A - Continuous operation type CO2-hydrate mixture cooling system - Google Patents

Abstract

The present invention is to provide a continuous operation type carbon dioxide-hydrate mixture secondary fluid cooling system capable of improving efficiency by continuously generating carbon dioxide-hydrate and using the carbon dioxide-hydrate as secondary fluid. The continuous operation type carbon dioxide-hydrate mixture secondary fluid cooling system comprises: a mixture tank having an internal receiving space; a carbon dioxide supply part to supply carbon dioxide to the mixture tank; a water supply part to supply water to the mixture tank; a chiller to cool the lower part of the mixture tank to generate carbon dioxide-hydrate slurry; a heating and dissociating part to heat-exchange external objects with the carbon dioxide-hydrate received after being generated in the mixture tank; a pump to supply the carbon dioxide-hydrate generated in the mixture tank to the heating and dissociating part; and a collection line having one end connected to the upper part of the mixture tank and the other end connected to the heating and dissociating part to collect the carbon dioxide-hydrate passing the heating and dissociating part to the mixture tank.

Description

[0001] Continuous operation type CO2-hydrate mixture cooling system [0002]

The present invention relates to a continuous operation type carbon dioxide-hydrate mixture secondary fluid cooling system, and more particularly, to a continuous-operation type carbon dioxide-hydrate secondary fluid cooling system which continuously generates carbon dioxide-hydrate and uses it as a secondary fluid to realize a cooling system. Lt; / RTI > fluid secondary cooling system.

Korean Patent Laid-Open Publication No. 10-2011-0054279 discloses that a gas hydrate is a special type of trapping compound whose appearance is white solid resembling ice but the crystal structure and physical properties of the material are very different. In addition, generally, under the conditions of high pressure and low temperature, void space called a pupil is generated in a three-dimensional lattice structure formed by hydrogen bonding between water molecules, and a low molecular weight gas molecule (methane, ethane, propane, carbon dioxide, Etc.) are physically captured and generated.

These gas hydrates have potential characteristics that can be applied to various industrial fields, and many studies have been conducted recently. It can be divided into five broad categories: securing fluidity, recovering energy resources, coping with climate change, transporting and storing gas, and safety associated with each of these areas.

Korean Patent Laid-Open Publication No. 10-2011-0054279 discloses an apparatus for producing gas hydrate in which water supplied from a water tank 11 is atomized by using an ultrasonic atomization apparatus 20 and is supplied to a reactor 30 And an ultrasonic vibrator (22) for introducing the water supplied from the upper part of the atomization-producing tank to the inside of the atomization-producing tank and introducing the water into the inside of the atomization-producing tank. The gas hydrate producing apparatus (10) A feed gas feed pipe 23 communicating with the atomization feed tank side to feed a gas hydrate generation gas as a feed gas and a feed gas containing water atomized in communication with the atomization feed tank side, And a circulation pipe (25) communicating with the bottom surface of the atomization-producing tank and transferring the non-atomized water to the water tank again. The mixed gas transfer pipe (24) Ultrasonic atomizing apparatus 20 with; A cooling jacket 32 installed on an outer wall of the reaction tank for cooling the reaction tank to generate a gas hydrate of a mixed gas supplied from a mixed gas inlet pipe communicated with the upper portion of the reaction tank, A gas hydrate discharge pipe 33 formed on the bottom of the reaction tank for discharging the gas hydrate produced by the reaction and an unreacted mixed gas discharge pipe 34 formed in the reaction tank for discharging unreacted mixed gas 30).

The gas hydrate produced by such a hydrate producing apparatus will have a feature of being excellent in efficiency as a secondary fluid. However, the hydrate production apparatus has a problem in that it is difficult to implement a configuration in which gas hydrate is continuously generated and supplied to the cooling system, so that it is difficult to apply it as a secondary fluid of the cooling system.

The present invention provides a continuous operation type carbon dioxide-hydrate mixture secondary fluid cooling system in which carbon dioxide-hydrate is continuously generated and used as a secondary fluid to improve the efficiency of the conventional prior art. .

The present invention also provides a continuous operation type carbon dioxide-hydrate mixture secondary fluid cooling system in which water and carbon dioxide are mixed at an appropriate pressure and an appropriate ratio to continuously produce carbon dioxide-hydrate and used as a secondary fluid.

The present invention relates to a mixing tank having an accommodation space formed therein; A carbon dioxide supply unit supplying carbon dioxide to the mixture tank; A water supply unit for supplying water to the mixture tank; A chiller for cooling the lower portion of the mixture tank to produce a carbon dioxide hydrate slurry; A heat dissipation unit for receiving the carbon dioxide hydrate produced in the mixture tank to heat-exchange the carbon dioxide hydrate with an external object; A pump for supplying the carbon dioxide hydrate produced in the mixture tank to the heat dissociation unit; And a recovery line connected to an upper portion of the mixture tank at one end and connected to the heat dissociation portion to recover the carbon dioxide hydrate passing through the heat dissociation portion to the mixture tank, wherein the continuous operation type carbon dioxide- hydrate mixture secondary fluid Cooling system.

Preferably, the internal pressure (P) of the mixture tank is 20 to 100 BAR, and the temperature in the tank is lower than the temperature (T) satisfying the formula (1).

[Equation 1]

P = 0.0383 * T2-0.0748 * T + 1.5813

In addition, the molar ratio of the initial carbon dioxide and water (the molar amount of water / the molar amount of carbon dioxide) supplied into the mixture tank is 60 or more.

The continuous operation type carbon dioxide-hydrate mixture secondary fluid cooling system according to the present invention can improve the cooling efficiency by continuously producing carbon dioxide-hydrate and using it as a secondary fluid.

Also, the continuous operation type carbon dioxide-hydrate mixture secondary fluid cooling system according to the present invention has an advantage that it can mix the water and carbon dioxide under proper conditions to continuously produce carbon dioxide-hydrate and use it as a secondary fluid.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a conventional apparatus for producing a gas hydrate; FIG.
2 is a block diagram of a continuous operation type carbon dioxide-hydrate mixture secondary fluid cooling system according to an embodiment of the present invention.
3 is a graph showing the carbon dioxide-hydrate region.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately The present invention should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

2, a continuous operation type carbon dioxide-hydrate mixture secondary fluid cooling system 100 according to an embodiment of the present invention includes a mixture tank 110, a carbon dioxide supply unit 120, a water supply unit 130, A heat dissipating unit 150, a pump 160, and a collecting line 170. [

The mixture tank 110 has a tank shape in which a space for receiving liquid and gas is formed.

The internal pressure P of the mixture tank 110 is maintained between 20 and 100 BAR and the temperature in the tank is maintained lower than a temperature T ° C. that satisfies the following formula 1 with respect to the current pressure P do.

At one side of the mixture tank 110, a carbon dioxide supply part 120 and a water supply part 130 for supplying carbon dioxide and water to the interior of the mixture tank are formed.

The carbon dioxide supply unit 120 is disposed at one side of the mixture tank 110 to supply carbon dioxide into the mixing tank 110 and the water supply unit 130 supplies water to the interior of the mixture tank 110 .

Between the carbon dioxide supply unit 120 and the mixture tank 110, a carbon dioxide control valve 121 may be formed to control the amount of carbon dioxide supplied from the carbon dioxide supply unit 120.

A water control valve 131 may be installed between the water supply unit 130 and the mixture tank 110 to control the amount of water supplied into the mixture tank 110.

Since the pressure of the mixture tank 110 can be determined by the carbon dioxide and water supplied by the carbon dioxide supply unit and the water supply unit, carbon dioxide and water are supplied according to the above-mentioned appropriate pressure of 20 to 100 BAR.

The molar ratio of the initial carbon dioxide and water (the molar amount of water / the molar amount of carbon dioxide) supplied from the carbon dioxide supplying unit 120 and the water supplying unit 130 is 60 or more.

The carbon dioxide-hydrate mixture is continuously produced in the mixture tank 110 when the conditions of the pressure, temperature, and initial carbon dioxide-water molar ratio of the mixture tank 110 are satisfied.

On the other hand, a chiller 140 is formed below the mixture tank 110. The chiller 140 may be a refrigeration system including a general compressor, a condenser, an expander, and an evaporator. It is needless to say that other refrigeration systems other than the general refrigeration system including the compressor, the condenser, the expander, and the evaporator can be applied as long as the lower portion 110b of the mixture tank 110 can be cooled to the set temperature.

The chiller 140 cools the lower part of the mixture tank 110 and maintains the internal temperature of the mixture tank 110 lower than the temperature T satisfying the above formula 1, 110b to produce carbon dioxide-hydrate in the form of slurry.

3, the chiller 140 is connected to the lower portion of the mixture tank 110 at a temperature corresponding to the pressure so that the lower pressure and temperature of the mixture tank 110 satisfy the pressure and temperature conditions of the hatched portion of FIG. .

The pump 160 transfers the carbon dioxide-hydrate produced in the mixture tank 110 to the heat dissipating unit 150. The pump 160 may be a general fluid pump that transfers fluid.

On one side of the pump 160, a heat dissipating unit 150 for supplying carbon dioxide-hydrate from the pump 160 and cooling an external object is formed. The heat dissociation unit 150 may be a heat exchanger commonly used in a refrigeration system. In the heat dissociation unit 150, the carbon dioxide-hydrate is dissociated and the surrounding heat is taken away to cool the external object.

The carbon dioxide-hydrate dissociated in the heat dissociation unit 150 is transferred to the upper portion 110a of the mixture tank 110 through the recovery line 170.

The recovery line 170 is connected to the upper portion of the mixture tank 110 at one end and connected to the heat dissociation unit 150 so that the carbon dioxide- To the upper portion 110a of the tank 110.

Hereinafter, a method of operating the continuous operation type carbon dioxide-hydrate mixture secondary fluid cooling system 100 according to an embodiment of the present invention will be described with reference to the accompanying drawings.

In order to operate the continuous-running type carbon dioxide-hydrate mixture secondary fluid cooling system 100, the carbon dioxide supply unit 120 and the water supply unit 130 firstly supply the molar ratio of the carbon dioxide and water (the molar amount of water / Is 60 or more, carbon dioxide and water are supplied to the mixture tank to form a pressure of 20 to 100 BAR in the mixture tank.

At the same time, the chiller 140 cools the lower portion of the mixture tank to maintain the temperature of the lower portion of the mixture tank at a temperature lower than the temperature (T) satisfying the expression (1), thereby forming a slurry- Allow hydrate to be formed.

When the carbon dioxide-hydrate slurry is produced in the lower part of the mixture tank 110, the pump 160 supplies the carbon dioxide-hydrate slurry to the heat dissociation unit 150.

The carbon dioxide-hydrate slurry supplied to the heating dissociation unit 150 is cooled while dissolving the external object. The dissociated carbon dioxide-hydrate is recovered to the upper portion of the mixture tank 110 through the recovery line 170, and is further converted into the carbon dioxide-hydrate slurry in the lower portion of the mixture tank, and recycled.

The carbon dioxide-hydrate cooling apparatus 100 can improve the cooling efficiency by continuously producing carbon dioxide-hydrate and using it as a secondary fluid. Further, the carbon dioxide-hydrate cooling apparatus 100 can mix the water and carbon dioxide under appropriate pressure and temperature conditions, Carbon dioxide-hydrate can be continuously produced and used as a secondary fluid.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: Carbon dioxide-hydrate mixture secondary fluid cooling system
110: Mixture tank 120: Carbon dioxide supply part
130: water supply unit 140: chiller
150: heating dissociation section 160: pump

Claims (3)

A mixing tank in which a receiving space is formed;
A carbon dioxide supply unit supplying carbon dioxide to the mixture tank;
A water supply unit for supplying water to the mixture tank;
A chiller for cooling the lower portion of the mixture tank to produce a carbon dioxide hydrate slurry;
A heat dissipation unit for receiving the carbon dioxide hydrate produced in the mixture tank to heat-exchange the carbon dioxide hydrate with an external object;
A pump for supplying the carbon dioxide hydrate produced in the mixture tank to the heat dissociation unit;
And a recovery line connected to an upper portion of the mixture tank at one end and connected to the heat dissociation portion to recover the carbon dioxide hydrate passing through the heat dissociation portion to the mixture tank, wherein the continuous operation type carbon dioxide- hydrate mixture secondary fluid Cooling system. The method according to claim 1,
Characterized in that the internal pressure (P) of the mixture tank is 20 to 100 BAR and the temperature in the tank is lower than the temperature (T) satisfying the following formula (1): ??? continuous operation type carbon dioxide- system
[Equation 1]

The method according to claim 1,
Wherein the molar ratio of the initial carbon dioxide and water (the molar amount of water / the molar amount of carbon dioxide) supplied into the mixture tank is 60 or more.

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