KR102098420B1 - Sea Water Supply System for Liquefied Gas Regasification Apparatus - Google Patents

Abstract

The present invention combines the operation cycle for discharging seawater into the ocean and the operation cycle for circulating without discharging seawater to selectively operate two operation modes according to the temperature of the seawater, thereby improving operational efficiency, and furthermore Disclosed is a seawater supply system for a liquefied gas regasifier that can be performed without stopping the regasification system when switching the operation mode between the discharge cycle and the circulation cycle, and can promptly compensate for an instantaneous lack of seawater in the line. The sea water supply system according to the present invention includes: a main supply line 100 connected from the intake port 10 to the regasification device 20; A main pump 102 installed in the main supply line 100; A discharge line 200 for discharging seawater circulated inside the regasification device 20; Recirculating seawater from the regasifier 20 by connecting the connection point (P1) in the middle of the discharge line (200) and the connection point (P2) of the main supply line (100) upstream of the main pump (102). A recovery line 300 for recovering hazards; The external discharge operation mode and the recovery line of seawater that discharge the seawater from the regasification device 20 to the outside through the discharge line 200 by selectively connecting the discharge line 200 and the recovery line 300 300) the seawater circulation control unit 700 for performing a control operation to select the seawater internal circulation operation mode to recirculate through; It is made including.

Description

Sea Water Supply System for Liquefied Gas Regasification Apparatus}

The present invention relates to a seawater supply system for supplying seawater as one of the heat sources for vaporization to a liquefied gas regasification apparatus, and more particularly, it combines an operation cycle for discharging seawater into the ocean and an operation cycle for circulating without discharging seawater. It improves the operation efficiency by allowing two operation modes to be selectively operated according to the temperature of the seawater. Furthermore, it can be performed without stopping the regasification system when switching the operation mode between the discharge cycle and the circulation cycle. The present invention relates to a seawater supply system for a liquefied gas regasification device that can promptly compensate for an instantaneous shortage of seawater.

A floating gas storage and regasification unit (FSRU) or a vessel equipped with a liquefied gas regasification facility (RV; Regasification Vessel) and the like are known.

In such a floating equipment or a regasification apparatus of a ship, sea water is taken and supplied to a heat exchanger of a regasification apparatus for use as a heat source for providing vaporization heat to liquefied gas, as described in Patent Documents 1 to 5. .

In general, LNG-FSRU ships often operate in hot regions, and when operating in cold regions or in winter, a steam heater is installed as a device to increase the temperature of the seawater, and after heating the seawater when the temperature of the seawater is low. It is sent to the regasifier.

However, even when the temperature of the seawater is increased by using the steam heater, since the seawater from the regasification device is discarded into the sea, the steam heater must be operated at all times, resulting in excessive energy consumption.

Republic of Korea Patent Publication No. 10-2015-0019520 (2015.02.25) Republic of Korea Patent Publication Publication No. 10-2015-0016792 (2015.02.11) Republic of Korea Patent Publication No. 10-2014-0082322 (2014.07.02) Republic of Korea Patent Publication Publication No. 10-2013-0109559 (2013.10.05) Republic of Korea Patent Publication Publication No. 10-2013-0011152 (2013.01.30)

According to the present invention, the operation cycle for discharging seawater into the ocean and the operation cycle for circulating without discharging seawater are combined to form a seawater supply system for a liquefied gas regasifier, thereby selectively operating two operation modes according to the temperature of seawater. It aims to improve the operation efficiency by making it possible.

Furthermore, when switching from one mode of operation to another, it is possible to perform smoothly without stopping the operation of the regasification system. It aims to make it possible to compensate for the phenomenon promptly and to enable smoother and more precise operation.

In order to achieve the above object, the seawater supply system for a liquefied gas regasification apparatus according to the present invention, the main supply line 100 connected to the regasification apparatus 20 from the intake port 10; A main pump 102 installed in the main supply line 100; A discharge line 200 for discharging seawater circulated inside the regasification device 20; Recirculating seawater from the regasifier 20 by connecting the connection point (P1) in the middle of the discharge line (200) and the connection point (P2) of the main supply line (100) upstream of the main pump (102). A recovery line 300 for recovering hazards; The external discharge operation mode and the recovery line of seawater that discharge the seawater from the regasification device 20 to the outside through the discharge line 200 by selectively connecting the discharge line 200 and the recovery line 300 300) the seawater circulation control unit 700 for performing a control operation to select the seawater internal circulation operation mode to recirculate through; It is made including.

In the seawater supply system for a liquefied gas regasification apparatus according to the present invention, on the downstream side of the connection point (P1). An opening / closing valve 202 is installed in the discharge line 200, and an opening / closing valve 302 is installed in the recovery line 200; The seawater circulation control unit 700 is preferably set to select the seawater external discharge operation mode and the seawater internal circulation operation mode by selectively opening and closing the on-off valve 202 and the on-off valve 302.

In the seawater supply system for a liquefied gas regasification apparatus according to the present invention, the main supply line 100 on the inlet side of the main pump 102 is connected to the main supply line 100 from the ship ballast tank 502 A seawater compensation line 500 for supplying ballast water additionally; A ballast water pump 504 installed in the seawater compensation line 500 to pump ballast water; An opening / closing valve 506 which is installed on the seawater compensation line 500 downstream of the ballast water pump 504 and opens and closes the flow of the ballast water by the control of the seawater circulation control unit 700; It may be configured to further include.

In the seawater supply system for a liquefied gas regasification apparatus according to the present invention, it is connected to a point downstream of the on-off valve 302 of the recovery line 300 to stabilize the flow inside the recovery line 300 (stabilization line ( 600); An expansion tank 602 installed in the stabilization line 600 to absorb changes in seawater volume in the recovery line 300 and prevent overflow or air intrusion; An on-off valve 604 that opens and closes the stabilization line 600; It may be configured to further include.

In the seawater supply system for a liquefied gas regasification apparatus according to the present invention, one point of the main supply line (100) upstream of the regasification apparatus (20) and the on / off valve (302) downstream recovery line (300) Bypass line 400 for returning without connecting the one point of the sea water to the regasifier 20; A bypass valve 402 installed on the bypass line 400 to open and close the bypass line 400 may be further included.

In the seawater supply system for a liquefied gas regasification apparatus according to the present invention, installed on the main supply line 100 downstream of the main pump 102, heat exchange with seawater flowing through the main supply line 100 by steam circulation It may further include a steam heater 120 to increase the temperature of the sea water.

In the seawater supply system for a liquefied gas regasification apparatus according to the present invention, the seawater circulation control unit 700, the open / close valve according to the temperature of the seawater in the main supply line 100 entering the regasification apparatus 20 ( 202) or opening and closing the valve 302 selectively to switch the operation mode; When the temperature of the seawater is higher than or equal to the set value, the opening / closing valve 302 is closed and the opening / closing valve 202 is controlled to open to select a seawater external discharge operation mode for discharging the seawater from the regasification device 20 to the outside. ; When the temperature of the seawater is less than the set value, the opening / closing valve 202 is closed and the opening / closing valve 302 is controlled to open to select a seawater internal circulation operation mode for recirculating seawater from the regasification device 20; It is desirable to program it.

According to the seawater supply system for a liquefied gas regasification device according to the present invention, since the 'outside seawater discharge operation form' for discharging seawater to the ocean and the 'internal seawater circulation operation mode' for circulating without discharging seawater can be selected, seawater Operational efficiency can be improved by selecting an operation mode suitable for the change of temperature condition or other conditions of

In addition, when switching from the 'outside seawater discharge operation mode' to the 'internal seawater circulation operation mode', the switching operation can be performed smoothly without stopping the operation of the regasification system. The sea water shortage can be compensated promptly by the sea water compensation line, and the pressure or volume fluctuations during operation are absorbed by the expansion tank, enabling smoother, more precise and stable operation.

1 is a system diagram of a seawater supply system for a liquefied gas regasification apparatus according to the present invention.
2 is a view for explaining the operation mode of the external discharge of sea water among the operation modes of the sea water supply system according to the present invention.
3 is a view for explaining the initial stage of the operation of the seawater internal circulation operation mode of the operation mode of the seawater supply system according to the present invention.
FIG. 4 is a view for explaining the driving mode after the initial stage of FIG. 3.

Hereinafter, embodiments of the seawater supply system for a liquefied gas regasification apparatus of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram of a seawater supply system for a liquefied gas regasification apparatus according to the present invention.

Referring to FIG. 1, a main supply line 100 for retrieving and supplying seawater from the sea from a floating marine facility or a sea chest 10 to a regasification device 20, a regasification device 20 ) The main pump 102 of the main supply line 100 from the discharge line 200 for discharging the seawater circulated inside the system to the outside of the system, one point in the middle of the discharge line 200 (connection point P1 in FIG. 1) ) Is connected to one point (connection point P2) between the on-off valve 104 and a circuit having a recovery line 300 for recovering the seawater from the regasification device 20 for recirculation.

In FIG. 1, reference numerals '22' and '24' in the regasification apparatus 20 are drawn with reference to a heat exchanger installed in the regasification apparatus 20, and reference numeral '22' is, for example, a 'vaporizer' May be, reference numeral '24' may be, for example, a 'heat exchanger (or preheater)' that primarily raises the temperature of the heat exchange medium (eg, propane) entering the vaporizer 22.

According to this circuit configuration, the so-called 'outside seawater discharge operation form' for discharging the seawater from the regasification device 20 to the outside of the system (eg, offshore or other demand within the facility) through the discharge line 200, It is equipped with all of the so-called 'seawater internal circulation operation patterns' that are sent back to the main pump 102 through the recovery line 300 and circulated again, so that any one operation mode can be selected and operated as needed.

The circulating process (process) of seawater for the regasification device 20 is performed by the command of the seawater circulation control unit 700, with the choice of the seawater external discharge operation mode and the seawater internal circulation operation mode.

In this specification and claims, the distinction between 'upstream' and 'downstream' is based on the normal flow direction of seawater. The normal flow direction of seawater is a direction flowing from the main pump 102 to the regasification device 20 in the main supply line 100, and a direction flowing from the regasification device 20 to the outside of the system in the discharge line 200. , In the recovery line 300 is a direction flowing from the regasifier 20 toward the main pump 102.

In the main supply line 100, a main pump 102 is installed, and an on-off valve 104 is installed on the upstream side of the main pump 102.

The main pump 102 pumps seawater, that is, seawater, from the water intake port 10 and pushes it toward the regasification device 20. The on-off valve 104 intermittently interrupts the main supply line 100 entering the main pump 102 from the intake port 10.

A sea water filter 110 and a steam heater 120 may be installed in the main supply line 100 downstream of the main pump 102.

The seawater filter 110 is a filter that filters foreign substances in the seawater flowing through the main supply line 100. The steam heater 120 is a heat exchanger for exchanging steam generated in a seawater flowing through the main supply line 100 and steam generated in a boiler, etc., and operates when the temperature of the seawater is low to increase the temperature of the seawater entering the regasification device 20. Plays a role.

The discharge line 200 is a line for discharging the seawater from the regasification device 20 to the outside of the system, and an opening / closing valve 202 is installed in the middle thereof.

The recovery line 300 extends by branching from one point on the upstream side of the on-off valve 202, that is, the connection point P1, and then the main pump 102 and the on-off valve 104 of the main supply line 100 ), That is, the connection point P2 is connected.

An on-off valve 302 is installed on the recovery line 300 downstream of the connection point P1.

The opening / closing valve 202 of the discharge line 200 and the opening / closing valve 302 of the recovery line 300 are selectively opened and closed according to two driving modes, and accordingly, the seawater exiting the regasification device 20 is a discharge line. It is discharged to the outside of the system through 200 or returned to the main pump 102 inlet side through the recovery line 300 and supplied to the regasifier 20 again through the main supply line 100.

In addition, in the present invention, a separate seawater compensation line 500 is provided to supply seawater instead of or in addition to seawater taken from the sea.

In the embodiment shown in FIG. 3, the 'ship ballast water' stored in the ballast water tank 502 of the ship can be additionally supplied as another type of sea water. The ballast tank 502 is filled with 'ship ballast water', which is sterilized seawater, in order to maintain a proper draft and balance of the ship.

Thus, the seawater compensation line 500 extends from the vessel ballast tank 502 and is connected to the main supply line 100 between the on-off valve 104 and the main pump 102. The seawater compensation line 500 is provided with a ballast water pump 504 that pumps up the ballast water from the ship ballast tank 502, while an on-off valve 506 is installed on the downstream side of the ballast water pump 504. The opening / closing valve 506 is opened and closed by the control of the seawater circulation control unit 700, and is opened when it is necessary to supply seawater in addition to the seawater flowing through the main supply line 100, thereby supplying the ballast water as additional seawater. Make it possible.

In particular, the additional supply of seawater (ballast water) through the seawater compensation line 500 is useful when switching from a seawater external discharge operation mode to a seawater internal circulation operation mode. That is, when switching from the external seawater discharge operation mode to the seawater internal circulation operation mode, a shortage of seawater appears that is short of seawater inside the recovery line 300, so immediately before, simultaneously with, or immediately after the changeover. , When the sea water compensation line 500 is opened to enable supply of ballast water, it is possible to compensate for the insufficient sea water in the recovery line 300, thereby contributing to more stable operation. In addition, even when the main supply line 100 on the intake port 10 side is urgently repaired, the on-off valve 104 is closed to block the main supply line 100 on the intake port 10 side and the seawater compensation line 500 is opened. When the ballast water of the ship is supplied as substitute seawater, the regasification device 20 can be operated continuously without stopping.

In addition, the seawater supply system of the present invention further includes a stabilization line 600 for stabilizing the flow of the seawater flow line.

The stabilization line 600 is connected to one point of the recovery line 300 downstream of the on-off valve 302 and is installed to communicate with the recovery line 300, and the expansion line (Expansion Tank) ( 602) is installed, and the on / off valve 604 for opening and closing the stabilization line 600 is installed.

The expansion tank 602 always maintains a fluid (eg, seawater) at a constant water level and is positioned at a high position to maintain a predetermined pressure head, absorbing a volume change according to the seawater temperature in the recovery line 300 and Prevent inflow or air intrusion so that stable operation is possible.

Therefore, the expansion tank 602 serves to stabilize the flow of the seawater circulation line when operating in the 'seawater internal circulation operation mode'.

In the present invention, the bypass line 400 and the line connecting one point of the main supply line 100 of the upstream side of the regasification apparatus 20 and one point of the recovery line 300 downstream of the on-off valve 302 and the line thereof It further includes an on-off valve 402 to regulate.

The bypass line 400 is for forming a circulation cycle that returns the seawater flowing through the main supply line 100 through the recovery line 300 without flowing into the regasification device 20. This is used to block the inflow of seawater to the regasification device 20 for maintenance of the regasification device 20 or to circulate seawater or detergent for inspection of the main supply line 100 and the recovery line 300. .

The seawater circulation control unit 700 selectively selects the on / off valve 202 or the on / off valve 302 according to the temperature of the seawater, that is, the temperature of the seawater in the main supply line 100 entering the regasification device 20. It is set to open and close with to switch the operation mode (programing).

That is, when the temperature of the seawater is higher than the set value (eg, 13 ° C), the recovery line 300 is closed and the opening / closing valve 302 is closed, and the main supply line 100 and the opening / closing valve 202 are controlled to open, thereby regasifying the device 20 ) Controls to operate in the 'outside seawater discharge operation mode' that discharges seawater from the outside.

On the other hand, when the temperature of the seawater is less than the set value (eg, 13 ° C. or higher), the discharge line 200 is closed and the valve 202 is closed and the recovery line 300 is opened and closed so that the valve 302 is opened to control the regasification device ( 20) It is controlled to operate in the 'seawater internal circulation operation mode' that recycles the seawater from the outside without discharging it.

Hereinafter, with reference to FIGS. 2 to 4, examples of the operation mode of the seawater supply system for a liquefied gas regasification apparatus of the present invention will be described.

FIG. 2 is a view for explaining an operation mode of 'outside seawater discharge' among operation modes of a seawater supply system according to the present invention. The line indicated by the thick solid line in the drawing is a line through which seawater flows.

The embodiment of Figure 2, for example, in the spring, summer, autumn, etc., the temperature of the sea water maintains a set value (eg; 13 ℃) or more, there is no need to use the steam heater 120, there is no energy consumption, thus recovering It shows a preferred mode of operation in the case of discharging the seawater from the fire apparatus 20 to the outside of the system as it is.

Referring to Figure 2, in the 'seawater discharge operation form', the seawater circulation control unit 700, the on-off valve 302, 402, 506, 604 is closed and the on-off valve 104, 202 is open The main pump 102 is operated, and the ballast water pump 504 is stopped.

In accordance with the operation of the main pump 102, seawater is pumped to the main supply line 100 through the intake port 10, filtered while passing through the seawater filter 110 of the main supply line 100, and the steam heater 120 ), Or bypass (as in this case, a steam heater is equipped with a bypass line), and then enter the regasification device 20 to perform heat exchange to vaporize the liquefied gas.

The seawater that has undergone heat exchange in the regasification device 20 is discharged to the outside of the system through the discharge line 200.

Next, FIG. 3 is a view for explaining the initial stage of operation of the 'seawater internal circulation operation mode' among the operation modes of the seawater supply system according to the present invention. The line indicated by the thick solid line in the drawing is a line through which seawater flows.

In the embodiment of FIG. 3, when the temperature of seawater is less than a set value (eg, 13 ° C), for example, in winter or in a cold region, it is necessary to preheat seawater using the steam heater 120. As a driving method, it shows a preferable driving mode in the case where it is desired to reduce energy consumption by reducing the load of the steam heater 120 by re-purifying seawater from the regasifier 20.

Referring to FIG. 3, when the temperature of the seawater falls below a set value, the seawater circulation control unit 700 operates in the 'outside seawater discharge operation mode' and then switches to the 'internal seawater circulation operation mode'. This is easily switched to performing a control operation in which the valves opened in the 'outside discharge operation mode of seawater' are closed and the valves opened are closed. However, the on-off valve 402 is kept closed.

That is, the seawater circulation control part 700 closes the open on-off valves 104 and 202, and opens and closes the open-close valves 302 and 506 and 604.

Then, the seawater exiting the regasification device 20 is not thrown out of the system and enters the main supply line 100 at the inlet side of the main pump 102 again through the recovery line 300, and then the main supply line 100 Through this, a cycle entering the regasification device 20 is performed again. Accordingly, by continuously circulating the seawater (the temperature is lower than the seawater on the sea side) exiting the regasification device 20, the load of the steam heater 120 is reduced (reducing the amount of steam to be supplied to the steam heater). Even if the steam heater 120 is operated only intermittently, it is possible to maintain the temperature of the circulating seawater above a set value.

On the other hand, immediately after switching from 'seawater external discharge operation mode' to 'seawater internal circulation operation mode', that is, immediately after the recovery line 300 is opened, the suction force of the main pump 102 suddenly acting in the recovery line 300 is applied. Thereby, there may also be a phenomenon in which the amount of seawater flowing in the recovery line 300 is insufficient due to the general cavitation phenomenon of the recovery line 300 due to the operation in the 'outside seawater discharge operation mode'.

Therefore, when switching from 'outside seawater discharge operation mode' to 'internal seawater circulation operation mode', seawater (ship ballast water) is additionally supplied and compensated through seawater compensation line 500.

To this end, immediately before switching to the 'seawater internal circulation operation mode', simultaneously with or immediately after switching, the ballast water pump 504 of the seawater compensation line 500 is operated and the opening / closing valve 506 is opened to balance the ship. It is controlled to pump the ballast water from the water tank 502 and supply it to the main supply line 100. It is preferable that the additional supply of ballast water through the seawater compensation line 500 is performed only for a predetermined time. That is, after a predetermined period of time, the supply is cut off, and a cycle of continuously recirculating seawater inside the circuit is performed (this simm will be described later with reference to FIG. 4).

On the other hand, during the additional supply of ballast water through the sea water compensation line 500, and when the sea water is compensated and the recirculation is continuously performed, pressure fluctuation or volume in the recovery line 300 according to the temperature change of the circulating sea water The fluctuations are absorbed by the expansion tank 602, so that a new operation mode, that is, operation in a 'seawater internal circulation operation mode' and seawater compensation operation can be stably performed.

Next, FIG. 4 is a diagram for explaining an operation mode of performing a recirculation cycle again after compensating the seawater through the seawater compensation line 500 for a predetermined time in the 'seawater internal circulation operation form'.

After the operation of additionally supplying the ballast water through the seawater compensation line 500 to the seawater that is insufficient in the recovery line 300 in the initial stage of the transition to the 'seawater internal circulation operation mode', the seawater circulation As shown in FIG. 4, the control unit 700 closes the on-off valve 506 and stops the operation of the ballast water pump 504. Then, a cycle of continuously recirculating only the seawater inside the circuit is performed without supplying seawater from the outside.

In the above, specific preferred embodiments of the present invention have been shown and described. However, the present invention is not limited to the above-described embodiments, and various modifications can be made to anyone having ordinary knowledge in the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims. .

10: water intake
20: regasifier
100: supply line
102: main pump
104: on-off valve
110: seawater filter
120: steam heater
200: discharge line
300: recovery line
400: bypass line
402: on-off valve
500: seawater compensation line
502: Ballast water tank
504: Ballast pump
506: on-off valve
600: stabilization line
602: expansion tank
700: seawater circulation control

Claims (7)

A main supply line 100 connected from the intake port 10 to the regasification device 20;
A main pump 102 installed in the main supply line 100;
A discharge line 200 for discharging seawater circulated inside the regasification device 20;
Recirculating seawater from the regasifier 20 by connecting the connection point (P1) in the middle of the discharge line (200) and the connection point (P2) of the main supply line (100) upstream of the main pump (102). Hazard recovery line 300;
A stabilization line 600 connected to a point of the recovery line 300 to stabilize the flow inside the recovery line 300;
It is installed on the stabilization line 600, the seawater is filled to maintain a constant water level therein, it is located at a higher position than the recovery line 300, and the recovery line 300 is generated by potential energy according to the height of the filled seawater. An expansion tank 602 that absorbs a volume change of seawater in the recovery line 300 and prevents overflow or air intrusion by applying pressure to the seawater within;
An on-off valve 604 that opens and closes the stabilization line 600; And
The external discharge operation mode and the recovery line of seawater that discharge the seawater from the regasification device 20 to the outside through the discharge line 200 by selectively connecting the discharge line 200 and the recovery line 300 300) the seawater circulation control unit 700 for performing a control operation to select the seawater internal circulation operation mode to recirculate through; Sea water supply system for a liquefied gas regasification apparatus comprising a. According to claim 1,
On the downstream side of the connection point (P1). An on-off valve 202 is installed on the discharge line 200, an on-off valve 302 is installed on the recovery line 200,
The seawater circulation control unit 700 is a seawater for liquefied gas regasification device that is set to select the seawater external discharge operation mode and seawater internal circulation operation mode by selectively opening and closing the on-off valve 202 and the on-off valve 302. Supply system. According to claim 1,
The sea water compensation line 500 that connects the main supply line 100 on the inlet side of the main pump 102 from the ship ballast tank 502 to additionally supply ship ballast water to the main supply line 100 ;
A ballast water pump 504 installed in the seawater compensation line 500 to pump ballast water;
An opening / closing valve 506 which is installed on the seawater compensation line 500 downstream of the ballast water pump 504 and opens and closes the flow of the ballast water by the control of the seawater circulation control unit 700; Sea water supply system for a liquefied gas regasifier further comprising a. delete According to claim 1,
Bypass line 400 that connects a point of the main supply line 100 on the upstream side of the regasification device 20 and a point of the recovery line 300 to return seawater without flowing into the regasification device 20. );
A seawater supply system for a liquefied gas regasification device, which is installed on the bypass line 400 and includes an opening / closing valve 402 for opening and closing the bypass line 400. According to claim 1,
The main pump (102) is installed on the main supply line (100) downstream, and includes steam steam (120) to increase the temperature of sea water by heat exchange with sea water flowing through the main supply line (100) by steam circulation. Sea water supply system for liquefied gas regasification device. According to claim 2,
The seawater circulation control unit 700,
Depending on the temperature of the seawater entering the regasification device 20, the opening and closing valve 202 or the opening and closing valve 302 is selectively opened and closed to switch the operation mode,
When the temperature of the seawater is higher than or equal to the set value, the opening / closing valve 302 is closed and the opening / closing valve 202 is controlled to open to select a seawater external discharge operation mode for discharging the seawater from the regasification device 20 to the outside. ,
When the temperature of the seawater is less than the set value, the on / off valve 202 is closed and the on / off valve 302 is controlled to open to set the seawater internal circulation operation mode for recirculating seawater from the regasification device 20. Sea water supply system for a liquefied gas regasification apparatus characterized in that.

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