KR20150030602A - High Stirring Reactor use Gas Hydrate Production Apparatus - Google Patents

Abstract

The present invention relates to an apparatus for continuously producing gas hydrate by high-speed stirring. According to the present invention, if clathrate hydrate is generated by using a high-speed stirring reactor, congestion is reduced. Formation of core and slurry is satisfactory by performing a high-speed reaction by using a magnetic drive and a teflon impeller which rotate at high speed in the opposite direction instead of an existing screw method. Transfer speed can be controlled, and stirring speed of each reactor can be differently controlled by adjusting the water level caused by a blocking separating plate formed between reactors. Also, hydrate slurry is discharged downwards in a final reactor so that congestion of an existing transportation process can be prevented.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a gas hydrate production apparatus using high-

The present invention relates to a technology capable of economically producing a mixed gas of natural gas or natural gas in a short time and economically as a crustate hydrate, and is characterized in that it is a high-speed agitator which is configured to shorten the production time of crustate hydrate and the gas filling rate The present invention relates to an apparatus for continuously producing a gas hydrate.

Generally, a clathrate hydrate or a gas hydrate is a hydrogen-bonded hydrogen molecule that forms a hydrogen-bonded solid lattice and a guest molecule that is trapped therein. Refers to a crystalline compound formed by physically trapping small molecules such as methane, ethane, and carbon dioxide in a three-dimensional lattice structure formed by water molecules through hydrogen bonding without chemical bonding.

There are about 130 known guest molecules that can be trapped in gas hydrate. For example, there are CH ₄ , C ₂ H ₆ , C ₃ H ₈ , CO ₂ , H ₂ , SF ₆ and the like. The crystal structures of the gas hydrate are composed of polyhedral cavities formed by water molecules composed of hydrogen bonds. Depending on the kind of the gas molecules and the conditions of production, the body-centered cubic structure I ), Diamond cubic structure II (II), and hexagonal structure H (sH). sI and sII are determined by the size of the object molecule, and in sH, the size and shape of the object molecule are important factors.

A reactor for producing such a clathrate hydrate or gas hydrate is provided in the prior art Patent No. 10-1213770 (entitled "Double Helical Gas Hydrate Reactor").

This prior art reactor comprises an inlet port through which water and gas are supplied; An outlet port located opposite the inlet port; A hollow jacket extending from the inlet port to the outlet port; A hollow outer shell disposed within the hollow jacket; And a double sheath gas hydrate reactor including an inner helical body located inside the outer helical body, wherein gas and water supplied through the inlet port in a channel between the inner helical body and the jacket are subjected to gas hydrate reaction, The outer helical body and the inner helical body rotate in the same direction and the winding directions of the outer helical blades of the outer helical body and the inner helical blades of the inner helical body are opposite to each other, The fluid flowing into the inner spiral flows in the direction opposite to the one direction so that some of the fluid reacts to become a gas hydrate and the other part of the fluid circulates continuously in the gas hydrate reactor do.

In the prior art, the gas hydrate slurry formed by the double helix principle is effectively discharged to the outside, and the unreacted water and gas are effectively circulated, thereby innovatively increasing the gas hydrate formation rate. In addition, It is possible to increase the gas hydrate formation rate by forming the gas hydrate evenly throughout the reactor by solving the problem that the efficiency is increased due to the concurrent operation and the temperature gradient between the outer wall side and the center side of the reactor is large. .

However, such a prior art is a screw type apparatus in which water is reacted with water while rotating the screw horizontally at a low speed in the reactor to produce a hydrate. This is because the clogging phenomenon is frequent and the stirring effect is low, Formation rate and slurry generation rate are low and the gas filling rate is low. In order to solve this problem, when the rotation speed of the screw is increased, the motor and the screw are damaged.

In order to shorten the saturation time and shorten the hydrate nucleation time by increasing the contact area between water and gas using rapid agitation, the present invention has been made to solve the problems of the related art by providing a Teflon impeller And a high speed agitation type magnetic drive for controlling the feed rate by adjusting the level of water in the reactor by means of the rotating force of the Teflon impeller and the blocking plate provided between the reactor and the gas hydrate It is an object to provide a continuous generation device.

In order to accomplish the above object, the present invention provides a method for increasing the filling rate of a hydrate slurry produced by growing a nucleus by reacting water and gas supplied to the interior thereof, A reactor having a discharge vessel for discharging the slurry conveyed from the fifth reaction vessel to the pelletizer, the reactor being connected to the fifth reaction vessel; A plurality of magnetic drives vertically installed in the upper portion of the 1-5th reaction vessel for high-speed stirring at a high pressure in the 1-5th reaction vessel; A plurality of Teflon shafts vertically installed on the magnetic drive so as to rotate at high speed; A tetron impeller disposed in the lower end of the Teflon shaft and disposed in the 1-5th reaction tank for conveying the hydrate sludge produced in each reaction tank; Slurry amount adjusting means for adjusting the amount of hydrate slurry provided between the first and second reaction vessels, the second and third reaction vessels, the third and fourth reaction vessels, the fourth and fifth reaction vessels, and the fifth reaction vessel and the discharge vessel; A digital template injector installed in the reactor for measuring the temperature of the liquid phase and the vapor phase; And a controller for controlling the supply of the water and the gas, and controlling the operation of the magnetic drive and the digital template indicator.

According to the present invention, clustering of crustate hydrate using a high-speed agitating reactor can reduce the clogging phenomenon. Instead of the conventional screw method, a high speed stirring reaction is performed using a magnetic drive and a Teflon impeller rotating at high speed in the opposite direction, The slurry formation is good and the conveying speed can be controlled by controlling the stirring rate of each reaction tank and the level of water by the blocking plate provided between each reaction tank. In the final reactor, the hydrate slurry is discharged to the bottom, Can be obtained.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram showing a first embodiment of a gas hydrate continuous production apparatus using high-speed agitation according to the present invention. FIG.
Fig. 2 is an enlarged view of the portion "A" in Fig.
Fig. 3 is an enlarged perspective view of the main part of Fig. 2; Fig.
FIG. 4 is an operational state diagram of a first embodiment of the apparatus for continuously generating gas hydrate using high-speed agitation according to the present invention. FIG.
5 is a view showing a second embodiment of the apparatus for continuously producing gas hydrate using high-speed agitation according to the present invention.
6 is an enlarged view of the portion "B" in Fig. 5; Fig.
FIG. 7 and FIG. 8 are operational state diagrams for a second embodiment of the apparatus for continuously producing gas hydrate using high-speed agitation according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic view showing a first embodiment of a stirring reactor for continuously producing a gas hydrate using a high-speed agitation according to the present invention. FIG. 2 is an enlarged view of the portion "A" FIG. 3 is an enlarged perspective view of the main part of FIG. 2, and FIG. 4 is an operational state diagram of the first embodiment of the apparatus for continuously producing gas hydrate using high-speed agitation according to the present invention.

As shown in FIGS. 1 to 4, the first embodiment of the apparatus for continuously producing gas hydrate using high-speed agitation according to the present invention comprises sequentially reacting water and gas supplied to the interior thereof, A plurality of first to fifth reaction tanks 1-5 communicated with each other to increase the filling rate of the hydrate slurry produced by growing and growing nuclei and a fifth reaction tank 5 communicating with the fifth reaction tank 5, A reactor (10) having a discharge vessel (6) for discharging the slurry conveyed from the reactor (5) to the pelletizer; A plurality of magnetic drives 20, which are vertically installed on the upper part of the 1-5th reaction tank 1-5 and have different speeds, are installed in the 1-5th reaction tank 1-5 in order to perform high- ; A plurality of Teflon shafts 30 vertically disposed at high speed in the magnetic drive 20; A tetron impeller 40 disposed at the lower end of the Teflon shaft 30 and positioned inside the No. 1-5 reaction vessel 1-5 for conveying the hydrate sludge produced in each reaction vessel; The first and second reaction vessels 1 and 2, the second and third reaction vessels 2 and 3, the third and fourth reaction vessels 3 and 4, the fourth and fifth reaction vessels 4 and 5, A slurry volume adjusting means (50) provided between the reaction tank (5) and the discharge tank (6) for adjusting the amount of hydrate slurry to be carried; A digital template indicator 60 installed in the reactor 10 for measuring the temperature of the liquid phase and the vapor phase; And a controller 70 for controlling the supply of water and gas supplied into the reactor 10 and for controlling the operation of the magnetic drive 20 and the digital templater indicator 60.

At this time, the controller 70 is connected to the LCD 72, and control values controlled by the controller 70 are displayed in characters and pictures.

A plurality of gases such as CH ₄ , C ₂ H ₆ , C ₃ H ₈ , CO ₂ , H ₂ and SF ₆ are present in the first reaction vessel 1 of the reactor 10, Water reacts in the reaction vessel to form slurry-like crustate hydrate.

The discharge vessel 6 is provided in communication with the fifth reaction vessel 5 to move the slurry conveyed from the fifth reaction vessel 5 to the pelletizer to produce crushed hydrate.

The slurry amount regulating means 50 includes first and second reactors 1 and 2 formed in a circular shape, second and third reactors 2 and 3, third and fourth reactors 3 and 4, (5), a fifth reaction tank (5), and a discharge tank (6), and is provided with a guide hole (52a); And a shielding separating plate 54 detachably coupled to the guide groove 52a of the rectangular hole 52 to selectively block the height of the rectangular hole 52. [

At this time, the height of the blocking partition plate 54 is kept equal to the water level of the water supplied into the 1-5th reaction tank 1-5. That is, the water and the gas are supplied automatically and continuously through the water supply line (A) and the gas supply line (B) so as to coincide with the height of the isolation partition plate (54).

In addition, the reactor 10 can be placed inside the cooling water tank 80 to cool the heat generated during the generation of the crustate hydrate, and then the temperature can be precisely controlled.

FIG. 5 is a configuration diagram showing a second embodiment of the apparatus for continuously producing gas hydrate using high-speed stirring according to the present invention, FIG. 6 is an enlarged view of the portion "B" FIG. 8 is an operational state diagram of a second embodiment of the apparatus for continuously generating gas hydrate using high-speed agitation according to the present invention.

This is a second embodiment of the apparatus for continuously producing gas hydrate using high-speed agitation, and the same components and elements as those of the first embodiment of Figs. 1 to 4 are denoted by the same reference numerals and signs.

As shown in FIGS. 5 to 8, the second embodiment of the apparatus for continuously producing gas hydrate using high-speed agitation according to the present invention comprises sequentially reacting water and gas supplied to the interior thereof, (1-5) provided in communication with the fifth reaction tank (5) so as to increase the filling rate of the hydrate slurry produced by growing the nucleus, and a fifth reaction tank (5) And a discharge vessel (6) for discharging the slurry flowing from the pelletizer to the pelletizer; In order to perform high-speed agitation in the high-pressure state inside the 1-5th reaction tank 1-5, a plurality of magnetic drives (hereinafter referred to as "20); A plurality of Teflon shafts 30 rotatably and vertically installed in the magnetic drive 20; A tetron impeller 40 disposed at the lower end of the Teflon shaft 30 and positioned inside the No. 1-5 reaction vessel 1-5 for conveying the hydrate sludge produced in each reaction vessel; The first and second reaction vessels 1 and 2, the second and third reaction vessels 2 and 3, the third and fourth reaction vessels 3 and 4, the fourth and fifth reaction vessels 4 and 5, A slurry amount adjusting means 90 provided between the reaction tank 5 and the discharge tank 6 for adjusting the amount of hydrate slurry to be conveyed; A digital template indicator 60 installed in the reactor 10 for measuring the temperature of the liquid phase and the vapor phase; And a controller 70 for controlling the supply of water and gas supplied into the reactor 10 and for controlling the operation of the magnetic drive 20 and the digital templater indicator 60.

At this time, the controller 70 is connected to the LCD 72, and control values controlled by the controller 70 are displayed in characters and pictures.

The discharge vessel 6 is provided in communication with the fifth reaction vessel 5 to move the slurry conveyed from the fifth reaction vessel 5 to the pelletizer to produce crushed hydrate.

The slurry amount regulating means 90 is formed in a circular shape and includes first and second reaction tanks 1 and 2 having upper openings, second and third reaction tanks 2 and 3, third and fourth reaction tanks 3, A plurality of rectangular holes 92 formed to communicate between the first and second reaction vessels 4 and 5, and the discharge vessel 6; And slopes 94 formed by sloping the upper and lower portions of the rectangular holes 92 and facilitating the transfer of the slurry produced by the rotation of the Teflon impeller 40 rotating in opposite directions to other reaction vessels.

At this time, the inclined surface 94 is sequentially formed in a direction facilitating the transportation of the slurry into the other reaction tank by the rotation of the Teflon impeller 40 rotating in the opposite direction.

On the other hand, the bottom surface of the rectangular hole 92 is kept equal to the water level of the water supplied into the 1-5th reaction tank 1-5. That is, water and gas are automatically and continuously supplied through the water supply line (A) and the gas supply line (B) so as to coincide with the bottom surface of the rectangular hole (92).

In addition, the reactor 10 can be placed inside the cooling water tank 80 to cool the heat generated during the generation of the crustate hydrate, and then the temperature can be precisely controlled.

The operation state of the apparatus for continuously generating gas hydrate using the high-speed stirring according to the first embodiment of the present invention will be schematically described.

When the controller 70 is operated as shown in FIGS. 1 to 3, water and gas are supplied through the water supply line A and the gas supply line B in accordance with the control program of the controller 70, And is filled in the reaction tank 1-5 and the discharge tank 6. That is, water and gas are supplied so as to coincide with the height of the shielding partition plate 54 constituting the slurry amount adjusting means 50 provided between the 1-5th reaction tank 1-5 and the discharge tank 6 .

The magnetic drive 20 is operated to rotate the plurality of magnetic drives 20 simultaneously at a speed preliminarily inputted by the control program of the controller 70 so that the Teflon shaft 30 and the Teflon impeller 40, So that the water and gas in the first to fifth reaction tanks 1-5 are stirred and warmed up for a predetermined time.

4, when the warming-up operation is completed for the set time, the magnetic drive 20, which is installed vertically above the 1-5th reaction tank 1-5 and is set at a different speed by the control program of the controller 70, The Teflon impeller 40 located inside the No. 1-5 reaction vessel 1-5 rotates the agitation speed differently and agitates the water and the gas so that the slurry type crustate hydrate is sequentially Respectively.

At this time, the speed of the magnetic drive 20 positioned in the first to third reaction tanks 1-3 is set to a high speed (300-500 rpm) and the speed of the magnetic drive 20 Is set to a low speed (200 rpm).

That is, the water and the gas are reacted with each other by the rotation of the Teflon impeller 40 located inside the sealed 1-5th reaction tank 1-5, The slurry amount and the conveying speed are controlled by adjusting the height of the partitioning plate 54 inserted in the guide groove 52a of the rectangular hole 52 constituting the slurry amount adjusting means 50. The slurry amount adjusting unit 50, 6) to transfer the slurry to a pelletizer to produce a pellet-type crustate hydrate.

At this time, water and gas are supplied through the water supply line (A) and the gas supply line (B) according to the control program of the controller (70) by the amount of water and gas transported and discharged to the discharge tank (6) Thereby filling the inside of the reaction tank 1-5, thereby enabling the production of continuous crustate hydrate.

5 and 6, the operation state of the gas hydrate continuous generator using the high-speed agitation according to the second embodiment will be schematically described.

First, the controller 70 is operated to supply water and gas to the inside of the 1-5th reaction tank 1-5 through the water supply line A and the gas supply line B in accordance with the control program of the controller 70 Fill. That is, water and gas are supplied so as to coincide with the height of the rectangular hole 92 constituting the slurry amount regulating means 90 provided between the No. 1-5 reaction tank 1-5 and the discharge tank 6 .

The magnetic drive 20 is operated to simultaneously rotate the plurality of magnetic drives 20 in the speed and rotational direction previously inputted by the control program of the controller 70 so that the Teflon shaft 30 and the Teflon impeller 40 are rotated, the water and gas in the first to fifth reaction tanks 1-5 are stirred to warm up for a predetermined time.

When the warming-up is completed for the set time, the magnetic drive 20, which is vertically installed on the upper part of the 1-5th reaction tank 1-5 and is set to have different speed and rotational direction by the control program of the controller 70, The Teflon impeller 40 located inside the No. 1-5 reaction tank 1-5 rotates in different directions in the rotating direction and the stirring speed to stir the water and the gas to form slurry type crustate hydrate Are sequentially generated.

7 and 8, when the Teflon impeller 40 of the closed first reaction tank 1 is rotated counterclockwise (see arrows), the rotation (anticlockwise) direction of the Teflon impeller 40 The crustate hydrate in the form of slurry produced in the first reaction tank 1 along the inclined surface 94 of the square through hole 92 formed between the first and second reaction tanks 1-2 is introduced into the second reaction tank 2, And is stirred by the Teflon impeller 40 of the second reaction vessel 2 rotating in the clockwise direction and is stirred in the rotation (clockwise) direction of the Teflon impeller 40 between the second and third reaction vessels 2-3 The slurry-like crustate hydrate produced in the second reaction tank 1 along the slope 94 of the square through hole 92 formed in the third reactor 3 is transferred to the third reaction vessel 3, Is stirred by the Teflon impeller 40 of the reaction tank 3 and is stirred in the rotation (anticlockwise) direction of the Teflon impeller 40 between the third and fourth reaction tanks 3-4 The crustate hydrate in the form of slurry produced in the third reaction tank 3 is conveyed to the fourth reaction tank 4 along the inclined surface 94 of the square through hole 92 formed in the fourth reaction tank 4, And the inclined surfaces 94 of the square through holes 92 formed between the 4-5th reaction vessels 4-5 in the rotation (clockwise) direction of the Teflon impeller 40 are agitated by the Teflon impeller 40 of the four- The slurry-form crustate hydrate produced in the fourth reaction tank 1 is conveyed to the fifth reaction tank 5 and is fed to the Teflon impeller 40 of the fifth reaction tank 5 rotating in the counterclockwise direction And is then agitated along the inclined surface 94 of the square through hole 92 formed between the fifth reaction tank 5 and the discharge tank 6 in the rotation (anticlockwise) direction of the Teflon impeller 40, ) Is delivered to the discharge vessel 6 to move the slurry to the pelletizer Resulting in pellet type crustate hydrate.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. .

1-5: Reactor 1-5 Reactor 6: Reactor
10: Reactor 20: Magnetic drive
30: Teflon shaft 40: Teflon impeller
50, 90: Slurry amount regulating means 52, 92:
52a: guide groove 54: shielding partition plate
60: Digital recorder Inducate 70: Controller
94: slope A: water supply line
B: gas supply line

Claims (6)

The first to fifth reaction vessels 1-5 are provided to communicate with each other to increase the filling rate of the hydrate slurry produced by growing the nuclei while sequentially passing through the saturation and nucleation steps by reacting water and gas supplied to the inside of the reactor, A reactor 10 communicating with the fifth reaction tank 5 and having a discharge tank 6 for discharging the slurry conveyed from the fifth reaction tank 5 to the pelletizer;
A plurality of magnetic drives 20 vertically installed on the upper part of the No. 1-5 reaction tank 1-5 for performing high-speed stirring in the high-pressure state inside the 1-5th reaction tank 1-5;
A plurality of Teflon shafts 30 vertically disposed at high speed in the magnetic drive 20;
A tetron impeller 40 disposed at the lower end of the Teflon shaft 30 and positioned inside the No. 1-5 reaction vessel 1-5 for conveying the hydrate sludge produced in each reaction vessel;
The first and second reaction vessels 1 and 2, the second and third reaction vessels 2 and 3, the third and fourth reaction vessels 3 and 4, the fourth and fifth reaction vessels 4 and 5, 5 slurry amount adjusting means 50 for adjusting the amount of hydrate slurry provided between the reaction tank 5 and the discharge tank 6;
A digital template Inducate 60 installed in the reactor 10 for measuring the temperature of the liquid phase and the vapor phase;
And a controller (70) for controlling the supply of the water and the gas and controlling the operation of the magnetic drive (20) and the digital templater indicator (60). 2. The apparatus according to claim 1, wherein the slurry volume adjusting means (50)
(2), (3), (3) and (4), (4), and (4) A fifth rectilinear hole 52 communicating between the fifth reaction tank 5 and the discharge tank 6 and having a guide groove 52a formed thereon;
And a shielding plate 54 detachably coupled to the guide groove 52a of the rectangular hole 52 to selectively block the height of the rectangular hole 52 to adjust the amount of slurry. Continuous gas hydrate generation system using high speed agitation. The method according to claim 1 or 2, wherein the height of the blocking partition plate (54) is maintained equal to the water level of water supplied into the 1-5th reaction tank (1-5) and the discharge tank (6) Continuous gas hydrate generation system using high speed agitation. The first to fifth reaction vessels (1- (1) to (5)) are connected in order to increase the filling rate of the grown hydrate slurry by reacting water and gas supplied to the inside, A reactor 5 communicating with the fifth reaction vessel 5 and having a discharge vessel 6 for discharging the slurry flowing from the fifth reaction vessel 5 to the pelletizer;
In order to perform high-speed agitation in the high-pressure state in the first to fifth reaction tanks 1-5, a plurality of magnetic drives (hereinafter referred to as "20);
A plurality of Teflon shafts 30 vertically disposed at high speed in the magnetic drive 20;
A tetron impeller 40 disposed at the lower end of the Teflon shaft 30 and positioned inside the No. 1-5 reaction vessel 1-5 for conveying the hydrate sludge produced in each reaction vessel;
The first and second reaction vessels 1 and 2, the second and third reaction vessels 2 and 3, the third and fourth reaction vessels 3 and 4, the fourth and fifth reaction vessels 4 and 5, 5 slurry volume adjusting means 90 for adjusting the amount of hydrate slurry carried between the reaction tank 5 and the discharge tank 6;
A digital template Inducate 60 installed in the reactor 10 for measuring the temperature of the liquid phase and the vapor phase;
And a controller (70) for controlling the supply of the water and the gas and controlling the operation of the magnetic drive (20) and the digital templater indicator (60). 5. The apparatus according to claim 4, wherein the slurry volume adjusting means (90)
(1), (2), (3) and (3), the third and fourth reaction vessels (3) and (4), and the fourth and fifth reaction vessels A plurality of rectangular holes 92 formed to communicate between the first reactor 4 (5), the fifth reactor 5, and the discharge vessel 6;
The upper and lower portions of the rectangular hole 92 are inclined in the same direction,
And a slope (94) formed to facilitate slurry transportation in the direction of rotation of the templer impeller (40) rotating in the opposite direction. 6. The method according to claim 4 or 5, wherein the bottom surface of the rectangular hole (92) is maintained at the same level as the water level supplied into the 1-5th reaction tank (1-5) Gas hydrate continuous generator.

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