KR20190125637A - Meg regeneration apparatus - Google Patents

Abstract

Disclosed by the present invention is an MEG regenerator. According to an embodiment of the present invention, the MEG regenerator includes: a reconcentration unit which includes a distillation tower of receiving rich MEG, from which low solubility salt is precipitated, from a pretreatment unit and evaporating water from the rich MEG by using a difference of boiling points between water and MEG to generate lean MEG, a reflux condenser of being provided at the top of the distillation tower and condensing water evaporated from the distillation tower, and a reflux drum of separating the condensed water into gas and liquid and returning a part of the liquid water to the distillation tower; a regeneration unit which is operated at a reduced pressure and includes a flash separator of receiving lean MEG, from which water is removed, from the reconcentration unit, and evaporating water from the lean MEG with MEG; a vacuum means which is provided at the front end of the reflux condenser or at the rear end of the reflux drum to allow the reconcentration unit to operate under a reduced pressure; and a salt dilution line which connects the distillation tower and the flash separator and supplies at least one part of the gas components evaporated by the flash separator to the distillation tower to prevent the precipitation of salt in the distillation tower. The present invention is provided to improve operation efficiency.

Description

MEG playback device {MEG REGENERATION APPARATUS}

The present invention relates to a MEG playback apparatus.

In the production of natural gas in the deep sea, water contained in natural gas is present as a hydrate due to the conditions of low temperature and high pressure. When supplying natural gas through a pipeline, hydrates can damage or corrode the inside of the pipeline and, in extreme cases, blockage of the pipeline or gas field can occur. Therefore, Mono Ethylene Glycol (MEG) is injected to suppress the formation of hydrates.

MEG has a strong hydrophilic ability to absorb moisture, and after being injected to suppress the formation of hydrates, MEG absorbs moisture in the gas and is recovered from the top of the offshore plant. The recovered MEG solution (hereinafter also referred to as “rich MEG”) contains impurities such as water, high soluble salts, and low soluble salts. The rich MEG can be extracted with high concentration of MEG by removing water and salts through the MEG regeneration process.

The MEG regeneration process is a full stream concept of removing salts by evaporating MEG solution at once, and partially removing low-solubility salts through water and then removing water, and then removing solid solution salts. There is a slip stream concept.

Specifically, the entire treatment method is a process of removing hydrocarbon from the rich MEG, removing the solid solution salt and the low solubility salt using flash, and then removing the water using the difference between the break points.

This entire process eliminates all salts by vaporization, so there is no problem with salts, but a large amount of energy is consumed because the entire MEG solution must be vaporized to remove salts.

Some treatments to compensate for these drawbacks include the removal of low-solubility salts and hydrocarbons from the rich MEG, followed by evaporation of water from the distillation column to produce lean MEG, followed by removal of the high-solution salt from lean MEG. Is done. Here, the product from the bottom of the distillation column is supplied, heated in the reboiler and returned to the distillation column to evaporate water from the rich MEG to produce lean MEG.

Some of these treatments classify salts that need to be removed into either high or low solubility salts. Low solubility salts are mainly divalent salts such as Ca 2+, Mg 2+, Ba 2+, and are not soluble in water. Solubility decreases with increasing temperature, causing precipitation. On the other hand, solid solution salts are mainly monovalent salts such as Na + and K + and are well soluble in water, and the solubility increases with increasing temperature.

On the other hand, some of the treatment methods described above are more energy efficient than the overall treatment methods, but scale deposition of salts may occur in the apparatus. For example, if the low-solubility salt is not sufficiently removed through the pretreatment process, a decrease in efficiency due to salt deposition may occur during evaporation of water from the rich MEG to form lean MEG. That is, the temperature of the lower portion of the distillation column is higher than the temperature of the low solubility salt removal process, and since the water is steadily removed from the distillation column, the concentration of the salt contained in the water is increased. This may cause salt deposition on the bottom of the distillation column and the reboiler, serious problems such as stopping the operation if the salt deposition is severe.

Please refer to Korean Patent Publication No. 10-2017-0059675 (published on May 31, 2017) as a technology related to the above.

Korean Patent Publication No. 10-2017-0059675 (published May 31, 2017)

An embodiment of the present invention is to provide a MEG regeneration device that effectively prevents scale deposition of salt to improve the efficiency of operation.

According to an aspect of the present invention, by receiving a rich MEG precipitated low-solubility salt from the pre-treatment unit using a difference between the break point between the water and MEG distillation column to produce lean MEG by evaporating water from the rich MEG, and the distillation tower A recondensation unit provided at the top of the column, including a reflux condenser for condensing the water evaporated from the distillation column, and a reflux drum separating gas-condensed water and returning a portion of the liquid water to the distillation column; A regeneration unit including a flash separator which is operated under reduced pressure and receives lean MEG from which water is removed from the reconcentration unit and evaporates water from the lean MEG together with the MEG; Vacuum means provided at a front end of the reflux condenser or at a rear end of the reflux drum to allow the reconcentration unit to be operated under reduced pressure; And a salt dilution line connecting the distillation column and the flash separator to each other and supplying at least a portion of gas components evaporated by the flash separator to the distillation column to prevent the precipitation of salt in the distillation column. May be provided.

The vacuum means may include an ejector provided at a front end of the reflux condenser and ejecting the driving fluid introduced into the first inlet at a high speed toward the outlet to suck gas components of the upper portion of the distillation column through the second inlet.

The vacuum means may be provided at the rear end of the reflux drum, and may include an ejector for ejecting the driving fluid introduced into the first inlet at high speed toward the outlet to suck the gas component of the reflux drum through the second inlet.

The vacuum means may include a first vacuum pump connected to a gas discharge line for discharging the gas component of the reflux drum, and the first vacuum pump may suck the gas component of the reflux drum through the gas discharge line.

The regeneration unit receives a lean MEG from which water is removed from the reconcentration unit, a flash separator for removing solid solution salt from the lean MEG, a regeneration condenser for condensing a gas component on the flash separator, and a regeneration condenser. A regeneration drum may further include a regeneration drum for gas-liquid separation of the condensed product, and the regeneration drum may be connected to a second vacuum pump and a suction line so that the regeneration unit may be depressurized by the second vacuum pump.

According to another aspect of the present invention, the distillation tower for receiving a rich MEG precipitated low-solubility salt from the pretreatment unit to produce a lean MEG by evaporating water from the rich MEG using the difference between the break point between the water and the MEG, and the distillation tower A recondensation unit provided at the top of the column, including a reflux condenser for condensing the water evaporated from the distillation column, and a reflux drum separating gas-condensed water and returning a portion of the liquid water to the distillation column; The flash separator is operated at a reduced pressure, receives lean MEG from which water is removed from the reconcentration unit, and flash flash to evaporate water from the lean MEG together with MEG, and receives and heats a lower product of the flash separator to be connected to the flash separator. Recirculation heater returning to the flash separator through the fourth circulation line and the bottom product of the flash separator is supplied through the salt removal circulation branch branched from the fourth circulation line to separate and remove the solid solution-in-sea salt component of the solid phase. A regeneration unit including a salt separator returning the remaining liquid component to the flash separator through the fourth circulation line; A vacuum means provided at a rear end of the reflux drum to allow the re-concentration unit to be operated under reduced pressure; And a salt dilution line branched from the salt separator rear end of the salt removing circulation line and injecting the liquid component separated by the salt separator into the distillation column.

The regeneration unit further includes a regeneration condenser for condensing gaseous components on the flash separator, and a regeneration drum for gas-liquid separation of the product condensed by the regeneration condenser, wherein the regeneration drum is connected to the vacuum means and a suction line. The regeneration unit can be operated under reduced pressure.

The vacuum means may include an ejector for ejecting the driving fluid introduced into the first inlet at high speed toward the outlet to suck the gas component of the reflux drum and the regeneration drum through the second inlet.

MEG regeneration apparatus according to an embodiment of the present invention can effectively prevent scale deposition of salt to improve the efficiency of operation.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 shows an MEG playback apparatus according to an embodiment of the present invention.
2 shows an MEG playback apparatus according to another embodiment of the present invention.
3 shows an MEG reproducing apparatus according to another embodiment of the present invention.
4 shows an MEG reproducing apparatus according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments introduced below are provided as an example to sufficiently convey the spirit of the present invention to those skilled in the art to which the present invention pertains. The present invention is not limited to the embodiments described below and may be embodied in other forms. Parts not related to the description are omitted in the drawings in order to clearly describe the present invention, in the drawings, the width, length, thickness, etc. of the components may be exaggerated for convenience. Like numbers refer to like elements throughout.

Referring to FIG. 1, the MEG regeneration apparatus 1000 according to an embodiment of the present invention removes impurities from the MEG solution recovered after being injected to suppress the generation of hydrates during natural gas production in the deep sea. High concentrations of MEG can be extracted. The MEG regeneration apparatus 1000 is operated in the ocean and may be applied to all ships and offshore structures that want to regenerate the MEG from the rich MEG recovered with natural gas after injecting the MEG into a subsea pipe. It can also be applied to land plants which require MEG regeneration processes.

The MEG reproducing apparatus 1000 includes a preprocessing unit 100, a reconcentrating unit 200, and a regenerating unit 300. Hereinafter, for convenience of description, the components are bundled and classified into the preprocessor 100, the reconcentrator 200, and the regenerator 300, but accordingly, the components may not be clearly divided. In the example, the classification may be different for convenience of description or due to an attribute of an element.

The pretreatment unit 100 has a hydrocarbon removal unit 110 for removing hydrocarbons contained in the rich MEG, a gas removal unit 120 for removing gas from the rich MEG from which hydrocarbons have been removed, and a gas removal unit 120. The pretreatment vessel 130 for depositing low solubility salt from the rich MEG and the rich MEG stored in the pretreatment vessel 130 are heated through a first circulation line L1 connected to the pretreatment vessel 130 to heat the pretreatment vessel ( And a centrifuge 150 for removing the low solubility salt precipitated from the pretreatment vessel 130 from the rich MEG.

Here, the rich MEG flowing into the hydrocarbon removal unit 110 may include less than about 50 wt% MEG. The hydrocarbon removal unit 110 removes the hydrocarbon mixed in the rich MEG, and the gas removal unit 120 removes the gas mixed in the rich MEG. The gas removed by the gas removing unit 120 may be discharged and processed through the gas removing line 121, and the rich MEG having passed through the hydrocarbon removing unit 110 and the gas removing unit 120 may be pretreated vessel 130. Is supplied.

The pretreatment vessel 130 may be maintained at a pressure higher than atmospheric pressure of about 1.5 bar, and precipitates the low-solubility salt in the rich MEG containing low-solubility salt, water and high-solubility salt. Low-solubility salts are mainly divalent salts, which do not dissolve well in water. As the temperature increases, solubility decreases, causing precipitation. Soluble salt is a monovalent salt that is well soluble in water, and its solubility increases with increasing temperature.

The pretreatment heater 140 receives and heats the rich MEG stored in the pretreatment vessel 130 through the first circulation line L1 connected to the pretreatment vessel 130, and circulates and supplies the pretreatment vessel 130 to the pretreatment vessel 130. (130) Low solubility salt is gradually precipitated inside. In other words, the rich MEG heated by the pretreatment heater 140 increases the temperature of the rich MEG stored in the pretreatment vessel 130 while repeatedly circulating, thereby causing low solubility salt from the rich MEG stored in the pretreatment vessel 130. Precipitates.

The centrifuge 150 removes the low-solubility salt crystals deposited through the pretreatment vessel 130 from the rich MEG, and the rich-solution MEG from which the low-solution salts have been removed is reconcentrated through the first connection line 101. Flows into).

Here, the first connection line 101 is the hydrocarbon removal unit 110, the gas removal unit 120, the pretreatment vessel 130, the pretreatment pump 135 and the centrifuge 150 of the pretreatment unit 100 and reconcentration. The distillation column 210 of the part 200 is connected.

The first circulation line L1 is branched from the rear end of the pretreatment pump 135 of the first connection line 101 and connected to the front end of the pretreatment pump 135 of the first connection line 101.

The reconcentration unit 200 receives a rich MEG from which low-solubility salt is removed from the pretreatment unit 100 and heats the distillation tower 210 to remove water therefrom, and a second circulation line L2 connected to the distillation tower 210. Reboiler 215 and the product received from the bottom of the distillation column 210 and heated to return to the distillation tower 210 and is provided in the top of the distillation tower 210, the water evaporated in the distillation tower 210 is distillation tower ( 210) includes a reflux condenser 220, a reflux drum 230 and a reflux pump 240 for supplying and condensing through a third circulation line L3 connected to the upper part and returning a part thereof to the distillation tower 210. .

The re-concentration unit 200 generates lean MEG by evaporating water from the rich MEG using the difference between the break points between the water and the MEG through the distillation column 210, and regenerating it through the second connection line 102. It may be supplied to the unit 300. In this case, the reconcentration unit 200 may remove approximately 80% to 90% of water from the rich MEG through the distillation column 210. The second connection line 102 connects the distillation column 210 of the reconcentration unit 200 and the flash separator 310 of the regeneration unit 300.

Specifically, the breaking point of the water contained in the rich MEG is 100 ° C at atmospheric pressure, the breaking point of the MEG is about 198 ° C, and the breaking point of the solid solution salt is much higher than that of the MEG.

Distillation column 210 may be operated between approximately 128 ℃ to 140 ℃ having a higher temperature than the pre-treated vessel 130 described above. The distillation column 210 may evaporate water having the lowest breaking point by heating the rich MEG, and may repeatedly evaporate water through the multi-stage distillation.

At this time, the reboiler 215 is supplied to the bottom of the distillation column 210 and heated to approximately 137 ℃ repeatedly circulated to the distillation column 210, through which the water is evaporated from the rich MEG stored in the distillation column 210 gradually Lean MEG is generated.

Some of these lean MEG is sent to the regeneration unit 300 through the second connection line 102, the other part of the rear end of the regeneration drum 340 of the third connection line 103 to be described later through the mixing line 104 After being introduced into, it is stored in the MEG storage tank (500).

The reflux condenser 220 condenses the water evaporated from the distillation column 210.

The reflux drum 230 gas-separates the water condensed by the reflux condenser 220. The reflux drum 230 may be connected to a gas discharge line 201 for discharging the gas component.

The reflux pump 240 re-supplies some of the liquid water discharged from the reflux drum 230 to the upper portion of the distillation column 210 through the third circulation line L3. At this time, the remaining portion of the liquid water discharged from the reflux drum 230 may be discharged through the condensate discharge line 202 connected to the rear end of the reflux pump 240 of the third circulation line (L3).

Here, the ejector 410 may be provided as a vacuum means in the front end of the reflux condenser 220 of the third circulation line (L3). The ejector 410 ejects the driving fluid introduced into the first inlet to the outlet at high speed to suck gas components from the upper part of the distillation tower 210 through the second inlet, and the distillation tower 210 and the reboiler in front of the ejector 410. Let 215 operate under reduced pressure in a vacuum state. The driving fluid is supplied toward the first inlet of the ejector 410 through the driving fluid supply line L5 connected to the ejector 410 and through the third circulation line L3 connected to the second inlet of the ejector 410. The gas component at the top of the distillation column 210 is sucked. The medium or high pressure driving fluid that has passed through the ejector 410 may be changed into a low pressure high temperature driving fluid. The driving fluid used in the ejector 410 may include, for example, steam or compressed air.

As a result, the re-concentration unit 200 may be operated under reduced pressure to reduce the temperature of the distillation column 210 to prevent the deposition of salt in the distillation column 210 and the reboiler 215.

As another example, referring to FIG. 2, an ejector 410 may be provided at a rear end of the reflux drum 230 of the third circulation line L3.

At this time, the ejector 410 ejects the driving fluid introduced into the first inlet through the driving fluid supply line L5 at a high speed toward the outlet to suck the gas component of the reflux drum 230 through the second inlet, and the ejector ( The reflux drum 230, the reflux condenser 220, the distillation column 210 and the reboiler 215 at the front end are operated under reduced pressure in a vacuum state.

As another example, referring to FIG. 3, a first vacuum pump 420 may be provided at the rear end of the reflux drum 230 as a vacuum means.

At this time, the first vacuum pump 420 is provided to be connected to the gas phase discharge line 201 for discharging the gas component of the reflux drum 230, and sucks the gas component of the reflux drum 230 through the gas phase discharge line 201 , The reflux drum 230, the reflux condenser 220, the distillation column 210 and the reboiler 215 of the front end to operate under reduced pressure in a vacuum state. The first vacuum pump 420 may include, for example, a liquid ring vacuum pump.

Through this, as in the ejector 410 described above, the reconcentration unit 200 may be operated under reduced pressure to prevent the salt from being deposited in the distillation column 210 and the reboiler 215.

1 to 3, the regeneration unit 300 receives lean MEG from which water is removed by the distillation column 210 through the second connection line 102, and flashes water to evaporate water from the lean MEG together with the MEG. A recirculation heater 320 that receives the product of the lower portion of the flash separator 310 through the fourth circulation line L4 connected to the flash separator 310 and heats it to return to the flash separator 310, The regeneration condenser 330 which is provided at the top of the flash separator 310 and condenses the gas component of the upper portion of the flash separator 310 and the regeneration drum 340 which vapor-separates the MEG condensed by the regeneration condenser 330 are provided. Include.

The flash separator 310 may be operated under reduced pressure, and a vacuum may be formed at an upper portion thereof by a vacuum distillation method using a principle that is easily evaporated in a vacuum state, thereby evaporating the lean MEG supplied from the reconcentration unit 200. . At this time, water is evaporated together with the MEG from the lean MEG introduced into the flash separator 310 to be converted into a gas state. Since the lean MEG supplied from the reconcentration unit 200 may contain about 10% to 20% of water, the gas component evaporated by the flash separator 310 may include water together with the MEG. In this case, the solid solution salt in the slurry state included in the flash separator 310 lower product that is not evaporated may be removed through the salt separator 325.

The salt separator 325 is branched from the rear end of the flash pump 315 of the fourth circulation line L4 to be provided in the salt removal circulation line 301 connected to the front end of the flash pump 315 of the fourth circulation line L4. Can be.

The salt separator 325 separates and removes the solid solution solution in solid form from the solid solution solution in the slurry state, and the remaining liquid component is the flash pump 315 of the fourth circulation line L4 through the salt removal circulation line 301. Return to the front end.

The flash pump 315 supplies the product under the regeneration unit 300 to the recirculation heater 320 through the fourth recirculation line L4. At this time, some of the product under the regeneration unit 300 is supplied to the salt removal circulation line (301).

The recirculation heater 320 receives the product of the lower portion of the flash separator 310 through the flash pump 315 and heats it to return to the upper portion of the flash separator 310.

Gas components (MEG and water) on the upper portion of the flash separator 310 are condensed by the regeneration condenser 330 and then supplied to the regeneration drum 340.

The regeneration drum 340 gas-separates the product condensed by the regeneration condenser 330. Regeneration drum 340 may be connected to the second vacuum pump 430 side and the suction line 302, through which the regeneration unit 300 is decompressed. That is, the regeneration drum 340, the regeneration condenser 330, the flash separator 310, and the recirculation heater 320 in front of the regeneration drum 340 may be operated under reduced pressure in a vacuum state. Liquid product (MEG and water) stored in the regeneration drum 340 is supplied to the MEG storage tank 500 through the third connecting line (103).

In this case, although not shown, the second vacuum pump 430 is omitted as another example, and the regeneration drum 340 and the front end of the first vacuum pump 420 of the gas phase discharge line 201 shown in FIG. The connection unit 302 may be connected to allow the regeneration unit 300 to operate under reduced pressure.

The third connection line 103 connects the flash separator 310, the regeneration condenser 330, the regeneration drum 340, and the MEG storage tank 500.

Here, the salt dilution line L6 branched from the front end of the regeneration condenser 330 of the third connection line 103 and connected to the lower part of the distillation column 210 may be provided. Salt dilution line (L6) is applicable to all of Figs.

Like the flash separator 310 operated under reduced pressure, the distillation column 210 is also operated under reduced pressure by the vacuum means of FIGS. 1 to 3 described above, and thus, a separate compression process is omitted, and among the gas components evaporated by the flash separator 310. Some may be supplied to the bottom of the distillation column 210.

That is, since the distillation column 210 is operated at atmospheric pressure in the related art, in order to supply some of the gas components evaporated by the flash separator 310 to the lower portion of the distillation column 210, a process of compressing the pressure requirements is necessary.

However, since the distillation column 210 is depressurized by the above-described vacuum means, such a compression process may be omitted and some of the gas components evaporated by the flash separator 310 may be directly supplied to the lower portion of the distillation column 210.

Since the gas component evaporated by the flash separator 310 has a very low salt content, when it is injected into the lower portion of the distillation column 210 through the salt dilution line L6, the salt is diluted to dilute the salt in the distillation tower 210. The phenomenon can be prevented.

As another example, referring to FIG. 4, the regeneration unit 300 operates under reduced pressure by connecting the regeneration drum 340 and the ejector 410 front end of the gas discharge line 201 illustrated in FIG. 2 through the suction line 302. You can do that. In this case, the first vacuum pump 420 may be used instead of the ejector 410.

Here, the above-described salt dilution line (L6) may be branched from the rear end of the salt separator 325 of the salt removal circulation line 301 may be connected to the lower portion of the distillation column (210). Through this, the remaining liquid component from which the solid solution-soluble salt component of the solid phase is removed by the salt separator 325 in the lower product of the flash separator 310 is injected into the distillation column 210, and the salt is diluted to dilute the salt in the distillation column 210. Precipitation can be prevented.

Meanwhile, the MEG storage tank 500 includes not only the liquid product of the regeneration drum 340 introduced through the third connection line 103 but also some of the lean MEG from which water is removed through the reconcentration unit 200. Also introduced through the mixing line 104 may be stored together. This can reduce the concentration of solubilized salts in lean MEG, and prevent the occurrence of scale due to solid solution.

In the MEG storage tank 500, MEG solution containing about 80 wt% or more of MEG, a small amount of water, and about 3 wt% or less of salt may be finally stored, and MEG may be additionally added if necessary.

MEG solution stored in the MEG storage tank 500 can be sent to the seabed to suppress the hydrate generation of the pipeline.

In the above, specific embodiments have been illustrated and described. However, the present invention is not limited only to the above-described embodiments, and those skilled in the art to which the present invention pertains can variously change variously without departing from the gist of the technical idea of the invention described in the claims below. Could be.

100: preprocessing unit 101: the first connection line
102: second connection line 103: third connection line
104: mixing line 110: hydrocarbon removal unit
120: gas removal unit 130: pretreatment vessel
140: pretreatment heater 150: centrifuge
200: reconcentrating unit 210: distillation tower
215: reboiler 220: reflux condenser
230: reflux drum 240: reflux pump
300: playback unit 310: flash separator
320: recycle heater 325: salt separator
330: recycled condenser 340: recycled drum
410: ejector 420: the first vacuum pump
430: second vacuum pump 500: MEG storage tank
L1: first circulation line L2: second circulation line
L3: third circulation line L4: fourth circulation line
L5: driving fluid supply line L6: salt dilution line

Claims (8)

The distillation column is provided at the top of the distillation column and a distillation column for generating a lean MEG by evaporating water from the rich MEG using a difference between the water and the MEG from the rich MEG having low solubility salt precipitated from a pretreatment unit. A recondensing unit comprising a reflux condenser for condensing the water evaporated from and a reflux drum separating gas-liquid condensed water and returning some of the liquid water to the distillation column;
A regeneration unit including a flash separator which is operated under reduced pressure and receives lean MEG from which water is removed from the reconcentration unit and evaporates water from the lean MEG together with the MEG;
Vacuum means provided at a front end of the reflux condenser or at a rear end of the reflux drum to allow the reconcentration unit to be operated under reduced pressure; And
And a salt dilution line connecting the distillation column and the flash separator to each other, and supplying at least a portion of gas components evaporated by the flash separator to the distillation column to prevent the precipitation of salt in the distillation column. The method of claim 1,
The vacuum means is provided in the front end of the reflux condenser, MEG regeneration apparatus including an ejector for injecting a gas flow in the upper portion of the distillation column through the second inlet by ejecting the drive fluid introduced into the first inlet at high speed. The method of claim 1,
The vacuum means is provided at the rear end of the reflux drum, MEG regeneration apparatus comprising an ejector for injecting the driving fluid introduced into the first inlet at high speed toward the outlet to suck the gas component of the reflux drum through the second inlet. The method of claim 1,
The vacuum means includes a first vacuum pump connected to the gas phase discharge line for discharging the gas component of the reflux drum,
And the first vacuum pump sucks gaseous components of the reflux drum through the gas discharge line. The method of claim 1,
The regeneration unit
A regenerated condenser condensing a gas component on the flash separator;
Further comprising a regeneration drum for gas-liquid separation of the product condensed by the regeneration condenser,
The regeneration drum is connected to the second vacuum pump and the suction line so that the regeneration unit is operated under reduced pressure by the second vacuum pump. The distillation column is provided at the top of the distillation column and a distillation column for generating a lean MEG by evaporating water from the rich MEG using a difference between the water and the MEG from the rich MEG having low solubility salt precipitated from a pretreatment unit. A recondensing unit comprising a reflux condenser for condensing the water evaporated from and a reflux drum separating gas-liquid condensed water and returning some of the liquid water to the distillation column;
The flash separator is operated at a reduced pressure, receives lean MEG from which water is removed from the reconcentration unit, and flash flash to evaporate water from the lean MEG together with MEG, and receives and heats a lower product of the flash separator to be connected to the flash separator. Recirculation heater returning to the flash separator through the fourth circulation line and the bottom product of the flash separator is supplied through the salt removal circulation branch branched from the fourth circulation line to separate and remove the solid solution-in-sea salt component of the solid phase. A regeneration unit including a salt separator returning the remaining liquid component to the flash separator through the fourth circulation line;
A vacuum means provided at a rear end of the reflux drum to allow the re-concentration unit to be operated under reduced pressure; And
And a salt dilution line branched from the salt separator rear end of the salt removing circulation line and injecting the liquid component separated by the salt separator into the distillation column. The method of claim 6,
The regeneration unit
A regenerated condenser condensing a gas component on the flash separator;
Further comprising a regeneration drum for gas-liquid separation of the product condensed by the regeneration condenser,
The regeneration drum is connected to the vacuum means and the suction line MEG regeneration device to operate the pressure reduction unit. The method of claim 7, wherein
The vacuum means includes an ejector for ejecting the driving fluid introduced into the first inlet at high speed toward the outlet to suck the reflux drum and the gas components of the regeneration drum through the second inlet.

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