Recovery system and recovery method of N-methyl-2-pyrrolidone waste liquid

文档序号:1333132 发布日期:2020-07-17 浏览:28次 中文

阅读说明:本技术 一种n-甲基-2-吡咯烷酮废液的回收系统和回收方法 (Recovery system and recovery method of N-methyl-2-pyrrolidone waste liquid ) 是由 张伟明 孙益辉 汪哲 于 2020-05-19 设计创作,主要内容包括:本发明提供一种N-甲基-2-吡咯烷酮废液的回收系统和回收方法,回收系统包括精馏塔、第一泵、沸石膜组件、第一热交换器和第二热交换器;精馏塔第三出口与第一泵连通后分两通路,其中一通路与沸石膜组件连通;沸石膜组件的渗余侧出口用于输出NMP产品流股;精馏塔第一出口与第一热交换器连通后分两通路,其中一通路用于输出废水组分。回收方法包括如下步骤:NMP废液经精馏塔精馏:塔顶流股进行热交换处理被冷凝后分两部分,其中一部分为废水组分;从集液单元采出的液相流股增压后分两部分,其中一部分进行沸石膜分离处理,以提供NMP产品流股。本发明使用单个精馏塔与沸石膜组件完成NMP的提纯,工艺流程短,对NMP废液的适应性强。(The invention provides a recovery system and a recovery method of N-methyl-2-pyrrolidone waste liquid, wherein the recovery system comprises a rectifying tower, a first pump, a zeolite membrane module, a first heat exchanger and a second heat exchanger; a third outlet of the rectifying tower is communicated with the first pump and then divided into two passages, wherein one passage is communicated with the zeolite membrane component; the outlet of the retentate side of the zeolite membrane module is used for outputting an NMP product stream; the first outlet of the rectifying tower is communicated with the first heat exchanger and then divided into two passages, wherein one passage is used for outputting wastewater components. The recovery method comprises the following steps: and (3) rectifying the NMP waste liquid by a rectifying tower: the tower top stream is subjected to heat exchange treatment and is condensed and divided into two parts, wherein one part is a wastewater component; the liquid phase stream withdrawn from the liquid collection unit is pressurized and split into two portions, one of which is subjected to a zeolite membrane separation process to provide an NMP product stream. The invention completes the purification of NMP by using a single rectifying tower and the zeolite membrane component, has short process flow and strong adaptability to NMP waste liquid.)

1. A recovery system of N-methyl-2-pyrrolidone waste liquid is characterized by comprising a rectifying tower (10), a first pump (20), a zeolite membrane component (30), a first heat exchanger (40) and a second heat exchanger (50);

a liquid collecting unit (11) is arranged in the rectifying tower (10); the rectifying tower (10) is also provided with: a first inlet (12) of the rectifying tower is used for inputting the waste liquid of the N-methyl-2-pyrrolidone; the second inlet (13) of the rectifying tower is arranged at the upper part of the rectifying tower (10); the third inlet (14) of the rectifying tower is arranged at the lower part of the rectifying tower (10); the fourth inlet (15) of the rectifying tower is arranged in the middle of the rectifying tower (10); a rectifying tower first outlet (16) arranged at the top of the rectifying tower (10); the second outlet (17) of the rectifying tower is arranged at the bottom of the rectifying tower (10); a third outlet (18) of the rectifying tower, which is communicated with the liquid collecting unit (11);

the third outlet (18) of the rectifying tower is communicated with the first pump (20) and then divided into two paths: one passage is communicated with the fourth inlet (15) of the rectifying tower to form reflux, and the other passage is communicated with the zeolite membrane module (30); the zeolite membrane module (30) is provided with a retentate side outlet (31) and a permeate side outlet (32), and the retentate side outlet (31) is used for outputting an N-methyl-2-pyrrolidone product stream; the permeate side outlet (32) for outputting a permeate stream;

the first outlet (16) of the rectifying tower is communicated with the first heat exchanger (40) and then divided into two paths: one passage is communicated with the second inlet (13) of the rectifying tower to form reflux, and the other passage is used for outputting wastewater components;

the second outlet (17) of the rectifying tower is divided into two paths: a path communicating with said third inlet (14) of said rectification column via said second heat exchanger (50) to form a reflux stream; the other path is used for outputting the heavy component.

2. The recycling system of N-methyl-2-pyrrolidone waste liquid of claim 1, further comprising at least one of the following technical features:

1) the heat exchanger further comprises a third heat exchanger (60), wherein the third heat exchanger (60) is provided with a third refrigerant inlet (611), a third refrigerant outlet (612), a third heating medium inlet (621) and a third heating medium outlet (622);

the third refrigerant inlet (611) is used for introducing N-methyl-2-pyrrolidone waste liquid, and the third refrigerant outlet (612) is communicated with the first inlet (12) of the rectifying tower; the retentate side outlet (31) is communicated with the third heating medium inlet (621), and the third heating medium outlet (622) is used for outputting an N-methyl-2-pyrrolidone product stream;

alternatively, the retentate side outlet (31) is in communication with the third heating medium inlet (621), the third heating medium outlet (622) is for outputting an N-methyl-2-pyrrolidone product stream;

2) the heat exchanger also comprises a fifth heat exchanger (100) which is provided with a fifth heat medium inlet (1011) and a fifth heat medium outlet (1012);

the fifth heating medium inlet (1011) is communicated with the permeation side outlet (32); the fifth heating medium outlet (1012) is used for outputting a penetrating fluid stream, or the fifth heating medium outlet (1012) is communicated with the first inlet (12) of the rectifying tower;

3) further comprising a first storage tank (70) for storing the N-methyl-2-pyrrolidone product stream;

4) further comprising a fourth heat exchanger (80); the fourth heat exchanger (80) is arranged on a passage of the third outlet (18) of the rectifying tower communicated with the zeolite membrane module (30);

5) further comprising a second pump (90); the second outlet (17) of the rectifying tower is communicated with the second pump (90) and then divided into two paths: a path communicating with said third inlet (14) of said rectification column via said second heat exchanger (50) to form a reflux stream; the other path is used for outputting heavy components, or the second outlet (17) of the rectifying tower is divided into two paths: a path communicating with said third inlet (14) of said rectification column via said second heat exchanger (50) to form a reflux stream; another passage communicates with the second pump (90) for outputting a heavy fraction;

6) the rectifying tower (10) is a filler rectifying tower or a plate-type rectifying tower;

7) the zeolite membrane in the zeolite membrane module (30) is a water priority permeable zeolite membrane;

8) a first liquid distribution unit (191), a second liquid distribution unit (192) and a third liquid distribution unit (193) are arranged in the rectifying tower (10), a first inlet (12) of the rectifying tower is communicated with the first liquid distribution unit (191), a second inlet (13) of the rectifying tower is communicated with the second liquid distribution unit (192), and a fourth inlet (15) of the rectifying tower is communicated with the third liquid distribution unit (193);

9) the first inlet (12) of the rectifying tower is arranged at the middle lower part of the rectifying tower (10);

10) the third outlet (18) of the rectifying tower is arranged in the middle of the rectifying tower (10);

11) and the third outlet (18) of the rectifying tower is positioned above the fourth inlet (15) of the rectifying tower.

3. The recycling system of N-methyl-2-pyrrolidone waste liquid of claim 1 or 2, wherein the recycling system further comprises at least one of the following technical features:

A) the device also comprises a third pump (110) and/or a second storage tank (120), wherein the third pump (110) and/or the second storage tank (120) are arranged on a passage before the first heat exchanger (40) is divided into two passages;

B) the rectifying tower further comprises a fourth pump (130) and/or a third storage tank (140), wherein the fourth pump (130) and/or the third storage tank (140) are arranged on a passage connecting the permeation side outlet (32) and the rectifying tower first inlet (12).

4. A system for recovering N-methyl-2-pyrrolidone waste liquid according to claim 1 or 3, wherein the recovery system further comprises at least one of the following technical features:

a) further comprising a sixth heat exchanger (150), the sixth heat exchanger (150) being provided with a sixth heat exchanger gas phase outlet (151) and a sixth heat exchanger liquid phase outlet (152);

the first heat exchanger (40) is provided with a first heat exchanger gas phase outlet (41) and a first heat exchanger liquid phase outlet (42);

the first heat exchanger gas phase outlet (41) is in communication with the sixth heat exchanger (150);

said sixth heat exchanger liquid phase outlet (152) is combined with said first heat exchanger liquid phase outlet (42) by piping and then divided into two passes; or, the sixth heat exchanger liquid phase outlet (152) and the first heat exchanger liquid phase outlet (42) are combined through a pipeline and then divided into two paths after passing through the third pump (110) and/or the second storage tank (120);

the two paths are as follows: one passage is communicated with the second inlet (13) of the rectifying tower to form reflux, and the other passage is used for outputting wastewater components;

the sixth heat exchanger gas-phase outlet (151) is used for outputting non-condensable gas;

b) the heat exchanger further comprises a seventh heat exchanger (160), wherein the seventh heat exchanger (160) is provided with a seventh heat exchanger gas-phase outlet (161) and a seventh heat exchanger liquid-phase outlet (162);

the fifth heat medium outlet (1012) is provided with a fifth heat medium gas phase outlet (10121) and a fifth heat medium liquid phase outlet (10122);

the fifth heat medium gas phase outlet (10121) is communicated with the seventh heat exchanger (160);

the seventh heat exchanger liquid phase outlet (162) and the fifth heat medium liquid phase outlet (10122) are combined through a pipeline and then communicated with the first inlet (12) of the rectifying tower; or the seventh heat exchanger liquid phase outlet (162) and the fifth heat medium liquid phase outlet (10122) are combined through a pipeline, then pass through the fourth pump (130) and/or the third storage tank (140), and then are communicated with the first inlet (12) of the rectifying tower;

the seventh heat exchanger gas phase outlet (161) is used for outputting non-condensable gas.

5. A system for recycling N-methyl-2-pyrrolidone waste liquid as defined in claim 3, further comprising at least one of the following technical features:

A1) in the characteristic A), a sixth heat exchanger (150) is further included, and the sixth heat exchanger (150) is provided with a sixth heat exchanger gas-phase outlet (151) and a sixth heat exchanger liquid-phase outlet (152);

the second storage tank (120) is also provided with a second storage tank gas phase outlet (121);

the second storage tank gas phase outlet (121) is communicated with the sixth heat exchanger (150), the sixth heat exchanger liquid phase outlet (152) is communicated with the second storage tank (120), and the sixth heat exchanger gas phase outlet (151) is used for outputting non-condensable gas;

B1) in the characteristic B), a seventh heat exchanger (160) is further included, and the seventh heat exchanger (160) is provided with a seventh heat exchanger gas-phase outlet (161) and a seventh heat exchanger liquid-phase outlet (162);

the third storage tank (140) is also provided with a third storage tank gas phase outlet (141);

the third storage tank gas-phase outlet (141) is communicated with the seventh heat exchanger (160), the seventh heat exchanger liquid-phase outlet (162) is communicated with the third storage tank (140), and the seventh heat exchanger gas-phase outlet (161) is used for outputting non-condensable gas.

6. The recovery system of N-methyl-2-pyrrolidone waste liquid of any one of claims 1 to 5, further comprising at least one of the following technical features:

1) the device also comprises a vacuum unit which is arranged on the first outlet (16) of the rectifying tower and/or on the passage of the outlet (32) on the permeation side;

2) the device also comprises a fourth storage tank (170) and a vacuum unit which are communicated, wherein the vacuum unit and the fourth storage tank (170) are arranged on a passage of the first outlet (16) of the rectifying tower;

3) the device also comprises a fifth storage tank (180) and a vacuum unit which are communicated, wherein the vacuum unit and the fifth storage tank (180) are arranged on the passage of the permeation side outlet (32).

7. A method for recovering N-methyl-2-pyrrolidone waste liquid is characterized by comprising the following steps:

and (3) rectifying the N-methyl-2-pyrrolidone waste liquid by a rectifying tower:

obtaining an overhead stream from the top of the column; the tower top stream is subjected to heat exchange treatment and is condensed and divided into two parts: one part of the waste water flows back to the rectifying tower, and the other part of the waste water flows back to the rectifying tower;

obtaining a bottom stream from the bottom of the column; the bottom stream is divided into two parts: one part of the heavy components flows back to the rectifying tower after heat exchange treatment, and the other part of the heavy components flows back to the rectifying tower;

a liquid phase stream extracted from a liquid collecting unit of the rectifying tower is pressurized and then divided into two parts: one part of the liquid phase stream is refluxed to the rectification column and the other part of the liquid phase stream is subjected to a zeolite membrane separation process to provide an N-methyl-2-pyrrolidone product stream and a permeate stream.

8. The method according to claim 7, wherein the method further comprises at least one of the following technical features:

1) performing heat exchange treatment on the N-methyl-2-pyrrolidone waste liquid and an N-methyl-2-pyrrolidone product stream provided by zeolite membrane separation treatment to provide a cooled N-methyl-2-pyrrolidone product stream and a heated N-methyl-2-pyrrolidone waste liquid, and rectifying the heated N-methyl-2-pyrrolidone waste liquid by using a rectifying tower;

2) performing heat exchange treatment on the penetrating fluid stream provided by the zeolite membrane separation treatment to provide a condensed penetrating fluid stream, or performing heat exchange treatment on the penetrating fluid stream provided by the zeolite membrane separation treatment and refluxing to the rectifying tower;

3) carrying out heat exchange treatment on the pressurized liquid phase flow and then carrying out zeolite membrane separation treatment; preferably, the temperature of the liquid phase stream after heat exchange treatment is 120-160 ℃;

4) the zeolite membrane is a water-priority permeable zeolite membrane;

5) the absolute pressure at the top of the rectifying tower is 0.5 kPa-20 kPa;

6) zeolite membrane separation treatment conditions: absolute pressure at the permeation side is less than or equal to 20kPa, and relative pressure at the retentate side is 0.1MPa to 1 MPa; preferably, the absolute pressure of the permeation side is 0.5kPa to 5kPa, and the relative pressure of the retentate side is 0.2MPa to 0.5 MPa;

7) the relative pressure of the pressurized liquid phase stream is 0.2 MPa-1.2 MPa.

9. The method for recovering N-methyl-2-pyrrolidone waste liquid according to claim 7 or 8, further comprising at least one of the following technical features:

1) after the tower top stream is subjected to heat exchange treatment and condensed, the tower top stream is divided into two parts after passing through a third pump and/or a second storage tank: one part of the waste water flows back to the rectifying tower, and the other part of the waste water flows back to the rectifying tower;

2) and after the penetrating fluid stream provided by the zeolite membrane separation treatment is subjected to heat exchange treatment and condensed, the penetrating fluid stream is introduced into a fourth pump and/or a third storage tank and then flows back to the rectifying tower.

10. The method for recovering N-methyl-2-pyrrolidone waste liquid according to claim 7 or 9, further comprising at least one of the following technical features:

A) performing heat exchange treatment on the tower top stream to provide a tower top heat exchange gas phase stream and a tower top heat exchange liquid phase stream;

the overhead heat exchange gas phase stream is subjected to a heat exchange treatment to provide a first gas phase stream and a first liquid phase stream;

the first liquid phase stream is mixed with the overhead heat exchange liquid phase stream and then divided into two parts; or the first liquid phase stream is mixed with the tower top heat exchange liquid phase stream and then is divided into two parts by a third pump and/or a second storage tank;

the two parts are as follows: one part of the waste water flows back to the rectifying tower, and the other part of the waste water flows back to the rectifying tower;

the first vapor phase stream is a non-condensable gas;

B) subjecting the permeate stream provided by the zeolite membrane separation process to a heat exchange process to provide a permeate gas phase stream and a permeate liquid phase stream;

the permeate vapor stream is heat exchanged to provide a second vapor stream and a second liquid stream;

the second liquid phase stream and the permeate liquid phase stream are mixed and then are introduced into a fourth pump and/or a third storage tank and then flow back to the rectifying tower;

the second vapor phase stream is a non-condensable gas.

11. The method according to claim 9, wherein the method further comprises at least one of the following technical features:

11) after the tower top stream is subjected to heat exchange treatment and condensed, the tower top stream passes through the second storage tank to provide a second storage tank gas phase stream and a second storage tank liquid phase stream;

the second storage tank vapor stream is subjected to a heat exchange treatment to provide a first vapor stream and a first liquid stream;

the first liquid phase stream is refluxed to the second storage tank and mixed with the second storage tank liquid phase stream;

the first vapor phase stream is a non-condensable gas;

21) the penetrating fluid stream provided by the zeolite membrane separation treatment is condensed after being subjected to heat exchange treatment and then passes through the third storage tank to provide a third storage tank gas phase stream and a third storage tank liquid phase stream;

the third storage tank vapor stream is subjected to a heat exchange treatment to provide a second vapor stream and a second liquid stream;

the second liquid phase stream is refluxed to the third drum and mixed with the third drum liquid phase stream;

the second vapor phase stream is a non-condensable gas.

12. The method for recovering N-methyl-2-pyrrolidone waste liquid according to any one of claims 9 or 11, further comprising at least one of the following technical features:

a) the second storage tank provides vacuum degree through the fourth storage tank and the vacuum unit, and non-condensable gas is obtained from an outlet of the vacuum unit;

b) the third storage tank provides vacuum degree through the fifth storage tank and the vacuum unit, and non-condensable gas is obtained from an outlet of the vacuum unit.

Technical Field

The invention relates to the technical field of treatment and recovery of industrial production waste liquid, in particular to a recovery system and a recovery method of N-methyl-2-pyrrolidone waste liquid.

Background

N-methyl-2-pyrrolidone (NMP, CAS:872-50-4) is used as an excellent solvent widely in the production process of lithium batteries, the used NMP is volatilized in the coating stage to form organic waste gas, and the NMP in the waste gas is recovered through treatment technologies such as condensation, absorption and the like to form NMP waste liquid.

The purification of NMP in the prior NMP waste liquid adopts a multi-tower rectification process to carry out light and heavy removal treatment on the NMP waste liquid and purify the NMP to an electronic grade product. For example, the NMP waste liquid recovery system described in CN207811625U includes a raw material tank, a one-column atmospheric dehydration column, a two-column vacuum dehydration column, a three-column NMP purification column, and a four-column high boiling substance concentration column, and the inlet and outlet are connected in this order. The multi-tower process has long flow, more process equipment and long retention time of NMP in the whole flow, and partial decomposition can affect the product quality. The purification of NMP in the prior NMP waste liquid sometimes adopts a single-tower process with a side line extraction, but the process is sensitive to feed variation and has unstable product quality.

Disclosure of Invention

The invention aims to provide a recovery system and a recovery method of N-methyl-2-pyrrolidone waste liquid, and aims to solve the problems that in the prior art, a multi-tower process is long in flow, multiple in process equipment, and a single-tower process with a side line extraction is sensitive to feeding change and unstable in product quality.

In order to achieve the above objects and other related objects, a first aspect of embodiments of the present invention provides a system for recovering N-methyl-2-pyrrolidone waste liquid, including a rectification column, a first pump, a zeolite membrane module, a first heat exchanger, and a second heat exchanger;

a liquid collecting unit is arranged in the rectifying tower; the rectifying tower is also provided with: the first inlet of the rectifying tower is used for inputting the waste liquid of the N-methyl-2-pyrrolidone; the second inlet of the rectifying tower is arranged at the upper part of the rectifying tower; the third inlet of the rectifying tower is arranged at the lower part of the rectifying tower; the fourth inlet of the rectifying tower is arranged in the middle of the rectifying tower; the first outlet of the rectifying tower is arranged at the top of the rectifying tower; the second outlet of the rectifying tower is arranged at the bottom of the rectifying tower; a third outlet of the rectifying tower is communicated with the liquid collecting unit;

and a third outlet of the rectifying tower is communicated with the first pump and then divided into two paths: one passage is communicated with the fourth inlet of the rectifying tower to form reflux, and the other passage is communicated with the zeolite membrane component; the zeolite membrane component is provided with a retentate side outlet and a permeate side outlet, and the retentate side outlet is used for outputting an N-methyl-2-pyrrolidone product stream; the permeate side outlet for outputting a permeate stream;

the first outlet of the rectifying tower is communicated with the first heat exchanger and then divided into two paths: one passage is communicated with the second inlet of the rectifying tower to form reflux, and the other passage is used for outputting wastewater components;

the second outlet of the rectifying tower is divided into two paths: a passage is communicated with a third inlet of the rectifying tower through the second heat exchanger to form reflux; the other path is used for outputting the heavy component.

In the recovery system of the embodiment, a single rectifying tower and a zeolite membrane component are used for purifying the N-methyl-2-pyrrolidone in the waste liquid, so that an electronic-grade product can be obtained, the process flow is short, the adaptability to the N-methyl-2-pyrrolidone waste liquid is high, the water content can be changed in a large range, the product quality is stable, and the operation is simple.

Preferably, the recovery system further comprises at least one of the following technical features:

1) the heat exchanger is provided with a third refrigerant inlet, a third refrigerant outlet, a third heat medium inlet and a third heat medium outlet;

the third refrigerant inlet is used for introducing N-methyl-2-pyrrolidone waste liquid, and the third refrigerant outlet is communicated with the first inlet of the rectifying tower; the retentate side outlet is communicated with the third heating medium inlet, and the third heating medium outlet is used for outputting an N-methyl-2-pyrrolidone product stream. The third heat exchanger is used for carrying out heat exchange on the stream output from the retentate side outlet and the N-methyl-2-pyrrolidone waste liquid, the N-methyl-2-pyrrolidone waste liquid is heated, the stream output from the retentate side outlet is cooled, the stream heat energy output from the retentate side outlet is effectively utilized, and energy consumption is saved.

Or the retentate side outlet is communicated with the third heating medium inlet, and the third heating medium outlet is used for outputting an N-methyl-2-pyrrolidone product stream. The third heat exchanger is used to cool the stream exiting the retentate side outlet, which is cooled.

2) The heat exchanger is provided with a fifth heat medium inlet and a fifth heat medium outlet;

the fifth heating medium inlet is communicated with the permeation side outlet; the fifth heating medium outlet is used for outputting a penetrating fluid stream, or the fifth heating medium outlet is communicated with the first inlet of the rectifying tower.

The fifth heat exchanger is used for condensing the stream output by the outlet of the permeation side, or further, the stream condensed by the fifth heat exchanger flows back to the rectifying tower, so that the treatment effect of the system is further improved.

3) A first storage tank is also included for storing the N-methyl-2-pyrrolidone product stream. The first storage tank may be in communication with a unit that outputs an N-methyl-2-pyrrolidone product stream.

4) A fourth heat exchanger is also included; the fourth heat exchanger is arranged on a passage of the third outlet of the rectifying tower communicated with the zeolite membrane component. The fourth heat exchanger is used to heat the stream to the zeolite membrane module to increase the permeation flux of the zeolite membrane in the zeolite membrane module to facilitate dehydration.

5) A second pump is also included; and a second outlet of the rectifying tower is communicated with a second pump and then is divided into two paths: a passage is communicated with a third inlet of the rectifying tower through the second heat exchanger to form reflux; the other passage is used for outputting heavy components, or the second outlet of the rectifying tower is divided into two passages: a passage is communicated with a third inlet of the rectifying tower through the second heat exchanger to form reflux; the other passage is communicated with the second pump and is used for outputting heavy components.

The second pump is used for pressurizing the introduced fluid and then dividing the pressurized fluid into two parts, wherein one part outputs heavy components, and the other part reflows to the rectifying tower through the second heat exchanger, or the second pump is used for pressurizing the introduced fluid and outputting the heavy components.

6) The rectifying tower is a filler rectifying tower or a plate-type rectifying tower.

7) The zeolite membrane in the zeolite membrane module is a water priority permeable zeolite membrane. The water in the fluid passed into the zeolite membrane module permeates the water-preferentially permeable zeolite membrane as a permeate stream.

8) The rectifying tower is internally provided with a first liquid distribution unit, a second liquid distribution unit and a third liquid distribution unit, a first inlet of the rectifying tower is communicated with the first liquid distribution unit, a second inlet of the rectifying tower is communicated with the second liquid distribution unit, and a fourth inlet of the rectifying tower is communicated with the third liquid distribution unit. The first liquid distribution unit, the second liquid distribution unit and the third liquid distribution unit are used for uniformly distributing introduced fluid, and the efficiency of the rectifying tower is improved.

9) The first inlet of the rectifying tower is arranged at the middle lower part of the rectifying tower.

10) And the third outlet of the rectifying tower is arranged in the middle of the rectifying tower.

11) And the third outlet of the rectifying tower is positioned above the fourth inlet of the rectifying tower.

Preferably, the recovery system further comprises at least one of the following technical features:

A) the first heat exchanger is divided into two paths, and the first heat exchanger is provided with a first pump and a second storage tank.

The third pump is used for pressurizing the introduced fluid and then dividing the pressurized fluid into two parts, wherein one part outputs the wastewater component, and the other part reflows to the rectifying tower. The second storage tank is used for buffering and storing the introduced fluid.

B) The rectifying tower further comprises a fourth pump and/or a third storage tank, wherein the fourth pump and/or the third storage tank are arranged on a passage connecting the permeation side outlet and the first inlet of the rectifying tower.

And the fourth pump is used for pressurizing the introduced fluid and then refluxing the pressurized fluid to the rectifying tower. The third storage tank is used for buffering and storing the introduced fluid.

Preferably, the recovery system further comprises at least one of the following technical features:

a) the heat exchanger also comprises a sixth heat exchanger which is provided with a sixth heat exchanger gas-phase outlet and a sixth heat exchanger liquid-phase outlet;

the first heat exchanger is provided with a first heat exchanger gas-phase outlet and a first heat exchanger liquid-phase outlet;

the first heat exchanger vapor outlet is in communication with the sixth heat exchanger;

the liquid phase outlet of the sixth heat exchanger and the liquid phase outlet of the first heat exchanger are combined through a pipeline and then divided into two passages; or the liquid phase outlet of the sixth heat exchanger and the liquid phase outlet of the first heat exchanger are combined through a pipeline and then are divided into two paths after passing through the third pump and/or the second storage tank;

the two paths are as follows: one passage is communicated with the second inlet of the rectifying tower to form reflux, and the other passage is used for outputting wastewater components;

and the gas phase outlet of the sixth heat exchanger is used for outputting non-condensable gas.

And the liquid phase outlet of the first heat exchanger is used for outputting condensed liquid. The sixth heat exchanger is used for further condensing the introduced fluid, the condensed liquid can flow back to the rectifying tower for further rectification treatment, the non-condensable gas is discharged, and the treatment effect of the system is further improved.

b) The heat exchanger also comprises a seventh heat exchanger, and the seventh heat exchanger is provided with a seventh heat exchanger gas-phase outlet and a seventh heat exchanger liquid-phase outlet;

the fifth heat medium outlet is provided with a fifth heat medium gas phase outlet and a fifth heat medium liquid phase outlet;

the fifth heat medium gas phase outlet is communicated with the seventh heat exchanger;

the liquid phase outlet of the seventh heat exchanger and the liquid phase outlet of the fifth heating medium are combined through a pipeline and then communicated with the first inlet of the rectifying tower; or the liquid phase outlet of the seventh heat exchanger and the liquid phase outlet of the fifth heat medium are combined through a pipeline and then communicated with the first inlet of the rectifying tower after passing through the fourth pump and/or the third storage tank;

and the gas phase outlet of the seventh heat exchanger is used for outputting non-condensable gas.

And the fifth heat medium liquid phase outlet is used for outputting the condensed liquid. The seventh heat exchanger is used for further condensing the introduced fluid, the condensed liquid can flow back to the rectifying tower for further rectification treatment, and the non-condensable gas is discharged, so that the treatment effect of the system is further improved.

More preferably, the recovery system further comprises at least one of the following technical features:

A1) in the characteristic A), the device also comprises a sixth heat exchanger, wherein the sixth heat exchanger is provided with a sixth heat exchanger gas-phase outlet and a sixth heat exchanger liquid-phase outlet;

the second storage tank is also provided with a second storage tank gas phase outlet;

the second storage tank gas-phase outlet is communicated with the sixth heat exchanger, the sixth heat exchanger liquid-phase outlet is communicated with the second storage tank, and the sixth heat exchanger gas-phase outlet is used for outputting non-condensable gas.

The second storage tank is used for gas-liquid separation, and the separated gas phase is discharged from a gas phase outlet of the second storage tank. The sixth heat exchanger is used for further condensing the introduced fluid, a liquid phase outlet of the sixth heat exchanger is used for outputting condensed liquid, and the condensed liquid can flow back to the rectifying tower for further rectification treatment; and the gas-phase outlet of the sixth heat exchanger is used for outputting non-condensable gas, and the non-condensable gas is discharged, so that the treatment effect of the system is further improved.

B1) In the characteristic B), the heat exchanger further comprises a seventh heat exchanger, and the seventh heat exchanger is provided with a seventh heat exchanger gas-phase outlet and a seventh heat exchanger liquid-phase outlet;

the third storage tank is also provided with a third storage tank gas phase outlet;

the gas phase outlet of the third storage tank is communicated with the seventh heat exchanger, the liquid phase outlet of the seventh heat exchanger is communicated with the third storage tank, and the gas phase outlet of the seventh heat exchanger is used for outputting non-condensable gas.

The third storage tank is used for gas-liquid separation, and the separated gas phase is discharged from a gas phase outlet of the third storage tank. The seventh heat exchanger is used for further condensing the introduced fluid, a liquid phase outlet of the seventh heat exchanger is used for outputting condensed liquid, and the condensed liquid can flow back to the rectifying tower for further rectification treatment; and a gas phase outlet of the seventh heat exchanger is used for outputting non-condensable gas, and the non-condensable gas is discharged, so that the treatment effect of the system is further improved.

Preferably, the recovery system further comprises at least one of the following technical features:

1) the vacuum unit is arranged at the first outlet of the rectifying tower and/or on a passage of the outlet at the permeation side.

The vacuum unit is used for maintaining the vacuum degree of the recovery system.

2) The rectifying tower further comprises a fourth storage tank and a vacuum unit which are communicated, wherein the vacuum unit and the fourth storage tank are arranged on a passage of the first outlet of the rectifying tower.

The fourth storage tank is used for stabilizing the pressure (vacuum degree) of the recovery system. In order to effectively control the working pressure, inert gas can be introduced, when the pressure is too low, the inert gas is supplemented to the recovery system, and the pressure is properly increased.

3) The device also comprises a fifth storage tank and a vacuum unit which are communicated, wherein the vacuum unit and the fifth storage tank are arranged on the passage of the outlet at the permeation side.

The fifth storage tank is used for stabilizing the pressure (vacuum degree) of the recovery system. In order to effectively control the working pressure, inert gas can be introduced, when the pressure is too low, the inert gas is supplemented to the recovery system, and the pressure is properly increased.

The second aspect of the embodiments of the present invention provides a method for recovering N-methyl-2-pyrrolidone waste liquid, including the following steps:

and (3) rectifying the N-methyl-2-pyrrolidone waste liquid by a rectifying tower:

obtaining an overhead stream from the top of the column; the tower top stream is subjected to heat exchange treatment and is condensed and divided into two parts: one part of the waste water flows back to the rectifying tower, and the other part of the waste water flows back to the rectifying tower;

obtaining a bottom stream from the bottom of the column; the bottom stream is divided into two parts: one part of the heavy components flows back to the rectifying tower after heat exchange treatment, and the other part of the heavy components flows back to the rectifying tower;

a liquid phase stream extracted from a liquid collecting unit of the rectifying tower is pressurized and then divided into two parts: one part of the liquid phase stream is refluxed to the rectification column and the other part of the liquid phase stream is subjected to a zeolite membrane separation process to provide an N-methyl-2-pyrrolidone product stream and a permeate stream.

In the recovery method, a single rectifying tower and a zeolite membrane are used for separation treatment to complete purification of the N-methyl-2-pyrrolidone in the waste liquid, so that an electronic-grade product can be obtained, the process flow is short, the adaptability to the N-methyl-2-pyrrolidone waste liquid is high, the water content can be changed in a large range, the product quality is stable, and the operation is simple.

Preferably, the recovery method further comprises at least one of the following technical features:

1) and carrying out heat exchange treatment on the N-methyl-2-pyrrolidone waste liquid and an N-methyl-2-pyrrolidone product stream provided by zeolite membrane separation treatment to provide a cooled N-methyl-2-pyrrolidone product stream and a heated N-methyl-2-pyrrolidone waste liquid, and rectifying the heated N-methyl-2-pyrrolidone waste liquid by using a rectifying tower.

The heat energy of the N-methyl-2-pyrrolidone product stream provided by zeolite membrane separation treatment is effectively utilized, and the energy consumption is saved.

2) And performing heat exchange treatment on the penetrating fluid stream provided by the zeolite membrane separation treatment to provide a condensed penetrating fluid stream, or performing heat exchange treatment on the penetrating fluid stream provided by the zeolite membrane separation treatment and refluxing to the rectifying tower.

The penetrating fluid stream provided by the zeolite membrane separation treatment is condensed by heat exchange treatment, the steam pressure difference of the easily permeable components on the two sides of the zeolite membrane is increased, and the permeation flux is favorably improved, or further, the penetrating fluid stream provided by the condensed zeolite membrane separation treatment flows back to the rectifying tower, so that the treatment effect of the system is further improved.

3) Carrying out heat exchange treatment on the pressurized liquid phase flow and then carrying out zeolite membrane separation treatment; preferably, the temperature of the liquid phase stream after the heat exchange treatment is 120-160 ℃.

And performing heat exchange treatment on the pressurized liquid phase stream to provide a heated liquid phase stream so as to increase the permeation flux of the zeolite membrane.

The zeolite membrane has larger permeation flux and more ideal separation coefficient when the temperature is in the numerical range, and is more favorable for dehydration. Too low a temperature may result in small permeation flux and poor dehydration effect; excessive temperatures can cause damage to the zeolite membrane and a reduced service life.

4) The zeolite membrane is a water-priority permeable zeolite membrane.

The water in the stream permeates the water-preferentially permeable zeolite membrane as a permeate stream.

5) The absolute pressure at the top of the rectifying tower is 0.5 kPa-20 kPa.

The pressure at the tower top is too low, the power consumption of a vacuum pump is too high, the condensation temperature is too low, and the cold energy consumption is too high; the pressure at the top of the tower is too high, the pressure at the bottom of the tower is too high, the energy required by reboiling the reboiler is large, the temperature is high, and a heating medium with higher temperature is required.

6) Zeolite membrane separation treatment conditions: absolute pressure at the permeation side is less than or equal to 20kPa, and relative pressure at the retentate side is 0.1MPa to 1 MPa; preferably, the absolute pressure of the permeation side is 0.5kPa to 5kPa, and the relative pressure of the retentate side is 0.2MPa to 0.5 MPa.

The operation pressure is in the range, the permeation flux and the separation coefficient are larger, the treatment capacity and the separation effect are better, and the overall cost is lower. The permeate side pressure is too high, the permeate flux is low, and the treatment capacity is influenced; the excessive pressure on the redundant side increases the power consumption, and the increase of the permeation flux is not obvious. The pressure of the permeation side is too low, the condensation temperature is too low, the condensation of the permeate is not facilitated, and the load of a vacuum pump is obviously increased; the pressure on the retentate side is too low, the raw material liquid may be partially vaporized, and the system cannot operate normally.

7) The relative pressure of the pressurized liquid phase stream is 0.2 MPa-1.2 MPa.

The relative pressure within the above numerical range is favorable for increasing the permeation flux of the zeolite membrane and for dehydration. The relative pressure lower than 0.2MPa may cause small permeation flux and poor dehydration effect; the permeation flux of the zeolite membrane with the relative pressure of more than 1.2Mpa is not obviously increased.

Preferably, the recovery method further comprises at least one of the following technical features:

1) after the tower top stream is subjected to heat exchange treatment and condensed, the tower top stream is divided into two parts after passing through a third pump and/or a second storage tank: one part of the waste water flows back to the rectifying tower, and the other part of the waste water is a waste water component.

The third pump is used for pressurizing the introduced fluid and then dividing the pressurized fluid into two parts, wherein one part outputs the wastewater component, and the other part reflows to the rectifying tower.

The second storage tank is used for buffering and storing the introduced fluid.

2) And after the penetrating fluid stream provided by the zeolite membrane separation treatment is subjected to heat exchange treatment and condensed, the penetrating fluid stream is introduced into a fourth pump and/or a third storage tank and then flows back to the rectifying tower.

And the fourth pump is used for pressurizing the introduced fluid and then refluxing the pressurized fluid to the rectifying tower.

The third storage tank is used for buffering and storing the introduced fluid.

Preferably, the recovery method further comprises at least one of the following technical features:

A) performing heat exchange treatment on the tower top stream to provide a tower top heat exchange gas phase stream and a tower top heat exchange liquid phase stream;

the overhead heat exchange gas phase stream is subjected to a heat exchange treatment to provide a first gas phase stream and a first liquid phase stream;

the first liquid phase stream is mixed with the overhead heat exchange liquid phase stream and then divided into two parts; or the first liquid phase stream is mixed with the tower top heat exchange liquid phase stream and then is divided into two parts by a third pump and/or a second storage tank;

the two parts are as follows: one part of the waste water flows back to the rectifying tower, and the other part of the waste water flows back to the rectifying tower;

the first vapor phase stream is a non-condensable gas.

And the tower top heat exchange gas phase flow is subjected to heat exchange treatment, so that introduced fluid is further condensed, the condensed liquid can be further recycled, non-condensable gas is discharged, and the treatment effect is further improved.

B) Subjecting the permeate stream provided by the zeolite membrane separation process to a heat exchange process to provide a permeate gas phase stream and a permeate liquid phase stream;

the permeate vapor stream is heat exchanged to provide a second vapor stream and a second liquid stream;

the second liquid phase stream and the permeate liquid phase stream are mixed and then are introduced into a fourth pump and/or a third storage tank and then flow back to the rectifying tower;

the second vapor phase stream is a non-condensable gas.

And the penetrating fluid gas-phase stream is subjected to heat exchange treatment, so that introduced fluid is further condensed, the condensed liquid can be further recycled, non-condensable gas is discharged, and the treatment effect of the system is further improved.

More preferably, the recovery method further comprises at least one of the following technical features:

11) after the tower top stream is subjected to heat exchange treatment and condensed, the tower top stream passes through the second storage tank to provide a second storage tank gas phase stream and a second storage tank liquid phase stream;

the second storage tank vapor stream is subjected to a heat exchange treatment to provide a first vapor stream and a first liquid stream;

the first liquid phase stream is refluxed to the second storage tank and mixed with the second storage tank liquid phase stream;

the first vapor phase stream is a non-condensable gas.

The second storage tank is used for gas-liquid separation to obtain a first gas phase flow. And the gas-phase stream of the second storage tank is subjected to heat exchange treatment, so that introduced fluid is further condensed, the condensed liquid can be further recycled, non-condensable gas is discharged, and the treatment effect of the system is further improved.

21) The penetrating fluid stream provided by the zeolite membrane separation treatment is condensed after being subjected to heat exchange treatment and then passes through the third storage tank to provide a third storage tank gas phase stream and a third storage tank liquid phase stream;

the third storage tank vapor stream is subjected to a heat exchange treatment to provide a second vapor stream and a second liquid stream;

the second liquid phase stream is refluxed to the third drum and mixed with the third drum liquid phase stream;

the second vapor phase stream is a non-condensable gas.

And the third storage tank is used for gas-liquid separation to obtain a second gas-phase flow. And the gas-phase stream of the third storage tank is subjected to heat exchange treatment, so that introduced fluid is further condensed, the condensed liquid can be further recycled, non-condensable gas is discharged, and the treatment effect of the system is further improved.

More preferably, the recovery method further comprises at least one of the following technical features:

a) the second storage tank provides vacuum degree through the fourth storage tank and the vacuum unit, and non-condensable gas is obtained from an outlet of the vacuum unit.

The fourth storage tank is used for stabilizing the pressure (vacuum degree) of the recovery system.

b) The third storage tank provides vacuum degree through the fifth storage tank and the vacuum unit, and non-condensable gas is obtained from an outlet of the vacuum unit.

The fifth storage tank is used for stabilizing the pressure (vacuum degree) of the recovery system.

The vacuum unit is used for maintaining the vacuum degree of the recovery system, can be a vacuum pump, and is used for extracting air from the unit to be extracted to obtain vacuum.

The above-mentioned non-condensable gas means gas in which dissolved air in the material, air leaked from the joint into the system, etc. cannot be condensed under the operating conditions.

The technical scheme has the following technical effects:

1) according to the embodiment of the invention, the recovery system and the recovery method of the N-methyl-2-pyrrolidone waste liquid use a single rectifying tower and a zeolite membrane component to complete the purification of the N-methyl-2-pyrrolidone in the waste liquid, so that an electronic grade product can be obtained, the process flow is short, the adaptability to the N-methyl-2-pyrrolidone waste liquid is strong, the water content can have a large variation range, the product quality is stable, and the operation is simple;

2) according to the embodiment of the invention, the retention time of the N-methyl-2-pyrrolidone in the whole process is short, and the decomposition can be effectively inhibited.

3) According to the embodiment of the invention, the moisture content of the liquid phase stream extracted from the liquid collecting unit of the rectifying tower can be in a large variation range, the influence of the moisture content variation on the zeolite membrane component is small, the control requirement on the rectifying tower can be reduced, and the industrial production is facilitated.

Drawings

FIG. 1 is a schematic view of a system for recovering waste N-methyl-2-pyrrolidone solution according to a first embodiment of the present invention.

Fig. 2 is a schematic view of a preferred recovery system of N-methyl-2-pyrrolidone waste liquid according to the first embodiment of the present invention.

FIG. 3 is a schematic view of a preferred system for recovering N-methyl-2-pyrrolidone waste liquid according to the first embodiment of the present invention.

FIG. 4 is a first schematic view of a system for recovering N-methyl-2-pyrrolidone waste liquid according to a second embodiment of the present invention.

FIG. 5 is a second embodiment of the present invention, schematically illustrating a system for recovering N-methyl-2-pyrrolidone waste liquid.

FIG. 6 is a schematic view of a system for recovering waste N-methyl-2-pyrrolidone solution according to a third embodiment of the present invention.

FIG. 7 is a schematic view of a system for recovering waste N-methyl-2-pyrrolidone solution according to a fourth embodiment of the present invention.

Reference numerals

10 rectifying tower

11 liquid collecting unit

12 first inlet of rectifying tower

13 second inlet of rectifying tower

14 third inlet of rectifying tower

15 fourth inlet of rectifying tower

16 first outlet of rectifying tower

17 second outlet of rectifying tower

18 third outlet of rectifying tower

191 a first liquid distribution unit

192 second liquid distribution unit

193 third liquid distribution unit

20 first pump

30 zeolite membrane module

31 retentate side outlet

32 permeate side outlet

40 first heat exchanger

41 gas phase outlet of first heat exchanger

42 first heat exchanger liquid phase outlet

50 second heat exchanger

60 third Heat exchanger

611 third refrigerant inlet

612 third refrigerant outlet

621 third heating medium inlet

622 third heating medium outlet

70 first storage tank

80 fourth Heat exchanger

90 second pump

100 fifth Heat exchanger

1011 fifth heat medium inlet

1012 fifth heating medium outlet

10121 fifth heat medium gas phase outlet

10122 fifth heat medium liquid phase outlet

110 third pump

120 second storage tank

121 gas phase outlet of second storage tank

130 fourth pump

140 third storage tank

141 third storage tank gas phase outlet

150 sixth heat exchanger

151 sixth heat exchanger gas phase outlet

152 sixth heat exchanger liquid phase outlet

160 seventh heat exchanger

161 gas phase outlet of seventh heat exchanger

162 seventh heat exchanger liquid phase outlet

170 fourth storage tank

180 fifth storage tank

Detailed Description

The following description of the embodiments of the present invention is provided for illustrative purposes, and other advantages and effects of the present invention will become apparent to those skilled in the art from the present disclosure.

It should be understood that the structures, ratios, sizes, and the like shown in the drawings and described in the specification are only used for matching with the disclosure of the specification, so as to be understood and read by those skilled in the art, and are not used to limit the conditions under which the present invention can be implemented, so that the present invention has no technical significance, and any structural modification, ratio relationship change, or size adjustment should still fall within the scope of the present invention without affecting the efficacy and the achievable purpose of the present invention. In addition, the terms "upper", "lower", "left", "right", "middle" and "one" used in the present specification are for clarity of description, and are not intended to limit the scope of the present invention, and the relative relationship between the terms and the terms is not to be construed as a scope of the present invention.

As shown in fig. 1, a first embodiment of the present invention provides a system for recovering N-methyl-2-pyrrolidone waste liquid, comprising a rectification column 10, a first pump 20, a zeolite membrane module 30, a first heat exchanger 40 and a second heat exchanger 50;

a liquid collecting unit 11 is arranged in the rectifying tower 10; the rectifying column 10 is further provided with: a first inlet 12 of the rectifying tower is used for inputting the waste liquid of the N-methyl-2-pyrrolidone; the second inlet 13 of the rectifying tower is arranged at the upper part of the rectifying tower 10; a third inlet 14 of the rectifying tower, which is arranged at the lower part of the rectifying tower 10; the fourth inlet 15 of the rectifying tower is arranged in the middle of the rectifying tower 10; a rectifying tower first outlet 16 arranged at the top of the rectifying tower 10; a second outlet 17 of the rectifying tower, which is arranged at the bottom of the rectifying tower 10; a third outlet 18 of the rectifying tower, which is communicated with the liquid collecting unit 11;

the third outlet 18 of the rectifying tower is communicated with a first pump 20 and then divided into two paths: one path is communicated with the fourth inlet 15 of the rectifying tower to form reflux, and the other path is communicated with the zeolite membrane component 30; the zeolite membrane assembly 30 is provided with a retentate side outlet 31 and a permeate side outlet 32, the retentate side outlet 31 being for outputting an N-methyl-2-pyrrolidone product stream; a permeate side outlet 32 for outputting a permeate stream;

the first outlet 16 of the rectifying tower is communicated with the first heat exchanger 40 and then divided into two paths: one passage is communicated with the second inlet 13 of the rectifying tower to form reflux, and the other passage is used for outputting wastewater components;

the second outlet 17 of the rectifying tower is divided into two paths: a path is communicated with the third inlet 14 of the rectifying tower through the second heat exchanger 50 to form reflux; the other path is used for outputting the heavy component.

In the recovery system of the embodiment, a single rectifying tower and a zeolite membrane component are used for purifying the N-methyl-2-pyrrolidone in the waste liquid, so that an electronic-grade product can be obtained, the process flow is short, the adaptability to the N-methyl-2-pyrrolidone waste liquid is high, the water content can be changed in a large range, the product quality is stable, and the operation is simple.

When the recovery system is used, the waste liquid of the N-methyl-2-pyrrolidone is introduced into the rectifying tower 10 through the first inlet 12 of the rectifying tower 10 for rectification: an overhead stream is obtained from the first outlet 16 of the rectifying tower, and is condensed by a first heat exchanger 40 and then divided into two parts: one part of the wastewater flows back to the rectifying tower 10, and the other part of the wastewater is a wastewater component; a bottom stream is obtained from the second outlet 17 of the rectification column; the bottom stream is divided into two parts: one part of the heavy components flows back to the rectifying tower 10 after being subjected to heat exchange treatment by the second heat exchanger 50, and the other part of the heavy components; a liquid phase flow obtained from a liquid collecting unit 11 of the rectifying tower 10 through a third outlet 18 of the rectifying tower is pressurized by a first pump 20 and then divided into two parts: one portion is refluxed to the rectification column 10 and the other portion is subjected to a zeolite membrane separation process by a zeolite membrane module 30 to provide an N-methyl-2-pyrrolidone product stream and a permeate stream.

In a preferred embodiment, the recycling system further includes a third heat exchanger 60, the third heat exchanger 60 is provided with a third refrigerant inlet 611, a third refrigerant outlet 612, a third heating medium inlet 621 and a third heating medium outlet 622;

as shown in fig. 3, the third refrigerant inlet 611 is used for introducing the N-methyl-2-pyrrolidone waste liquid, and the third refrigerant outlet 612 is communicated with the first inlet 12 of the rectifying tower; the retentate side outlet 31 is in communication with a third heating medium inlet 621 and a third heating medium outlet 622 is used to output an N-methyl-2-pyrrolidone product stream. The third heat exchanger 60 is used for performing heat exchange between the stream output from the retentate side outlet 31 and the N-methyl-2-pyrrolidone waste liquid, heating the N-methyl-2-pyrrolidone waste liquid, cooling the stream output from the retentate side outlet 31, effectively utilizing the heat energy of the stream output from the retentate side outlet 31, and saving energy consumption.

Alternatively, as shown in fig. 2, the retentate side outlet 31 is in communication with a third heating medium inlet 621, and a third heating medium outlet 622 is used to output an N-methyl-2-pyrrolidone product stream. The third heat exchanger 60 is used to cool the stream exiting the retentate side outlet 31, which stream exiting the retentate side outlet 31 is cooled.

In a preferred embodiment, the recycling system further includes a fifth heat exchanger 100 provided with a fifth heating medium inlet 1011 and a fifth heating medium outlet 1012;

the fifth heating medium inlet 1011 is communicated with the permeate side outlet 32; the fifth heating medium outlet 1012 is used to output a permeate stream, or the fifth heating medium outlet 1012 is in communication with the first inlet 12 of the rectification column.

The fifth heat exchanger 100 is used for condensing the stream output from the permeate side outlet 32, or, further, the stream condensed by the fifth heat exchanger 100 is returned to the rectifying tower 10, thereby further improving the treatment effect of the system.

In a preferred embodiment, the recovery system further comprises a first storage tank 70 for storing the N-methyl-2-pyrrolidone product stream. The first storage tank 70 may be in communication with a unit that outputs an N-methyl-2-pyrrolidone product stream, such as: communicating with the retentate side outlet 31.

In a preferred embodiment, the recovery system further comprises a fourth heat exchanger 80; a fourth heat exchanger 80 is provided in the path of the rectification column third outlet 18 in communication with the zeolite membrane module 30. The fourth heat exchanger 80 is used to heat the stream to the zeolite membrane module to increase the permeation flux of the zeolite membrane in the zeolite membrane module to facilitate dehydration.

In a preferred embodiment, the recovery system further comprises a second pump 90; the second outlet 17 of the rectifying tower is communicated with a second pump 90 and then divided into two paths: a path is communicated with the third inlet 14 of the rectifying tower through the second heat exchanger 50 to form reflux; the other path is used for outputting heavy components, or the second outlet 17 of the rectifying tower is divided into two paths: a path is communicated with the third inlet 14 of the rectifying tower through the second heat exchanger 50 to form reflux; the other passage communicates with a second pump 90 for outputting the heavy fraction. The second pump 90 is used for pressurizing the introduced fluid and then dividing the pressurized fluid into two parts, wherein one part outputs heavy components, and the other part reflows to the rectifying tower through the second heat exchanger 50, or the second pump 90 is used for pressurizing the introduced fluid and outputting the heavy components.

The rectifying tower 10 is a packed rectifying tower or a plate rectifying tower. Fig. 1 shows a packing rectification column, and the liquid distributor of the packing rectification column may be a tray-type liquid distributor, a narrow-trough type liquid distributor, or other existing liquid distributors, and can meet the liquid distribution requirement.

The zeolite membrane in the zeolite membrane module 30 is a water-priority permeable zeolite membrane. The water in the fluid passed into the zeolite membrane module permeates the water-preferentially permeable zeolite membrane as a permeate stream.

As shown in fig. 1, in a preferred embodiment, a first liquid distribution unit 191, a second liquid distribution unit 192 and a third liquid distribution unit 193 are provided in the rectifying tower 10, the rectifying tower first inlet 12 is communicated with the first liquid distribution unit 191, the rectifying tower second inlet 13 is communicated with the second liquid distribution unit 192, and the rectifying tower fourth inlet 15 is communicated with the third liquid distribution unit 193. The first liquid distribution unit 191, the second liquid distribution unit 192 and the third liquid distribution unit 193 are used for uniformly distributing the introduced fluid, thereby improving the efficiency of the rectifying tower.

The rectifying tower first inlet 12 is provided at the middle lower portion of the rectifying tower 10.

The third outlet 18 of the rectifying tower is arranged in the middle of the rectifying tower 10.

The third outlet 18 of the rectifying column is located above the fourth inlet 15 of the rectifying column.

As shown in fig. 4 and 5, in a preferred second embodiment, the recycling system further includes a third pump 110 and/or a second storage tank 120, and the third pump 110 and/or the second storage tank 120 are provided on a path before the first heat exchanger 40 is divided into two paths. Specifically, the following connection means may be available:

the first outlet 16 of the rectifying tower is sequentially communicated with the third pump 110 through the first heat exchanger 40 and then divided into two passages;

or, the first outlet 16 of the rectifying tower is sequentially communicated with the second storage tank 120 through the first heat exchanger 40 and then divided into two paths;

or, the first outlet 16 of the rectifying tower is sequentially communicated with the first heat exchanger 40, the second storage tank 120 and the third pump 110 and then divided into two paths;

the two paths are: one path is communicated with the second inlet 13 of the rectifying tower to form reflux, and the other path is used for outputting waste water components.

The third pump 110 is used for pressurizing the introduced fluid and dividing the pressurized fluid into two parts, wherein one part outputs the wastewater component, and the other part reflows to the rectifying tower. The second reservoir 120 is used to buffer and store the incoming fluid.

In a preferred third embodiment, as shown in fig. 6, the recovery system further comprises a sixth heat exchanger 150, the sixth heat exchanger 150 being provided with a sixth heat exchanger vapor phase outlet 151 and a sixth heat exchanger liquid phase outlet 152;

the first heat exchanger 40 is provided with a first heat exchanger gas phase outlet 41 and a first heat exchanger liquid phase outlet 42;

the first heat exchanger gas phase outlet 41 communicates with the sixth heat exchanger 150;

the sixth heat exchanger liquid phase outlet 152 is combined with the first heat exchanger liquid phase outlet 42 by a pipeline and then divided into two paths; alternatively, the sixth heat exchanger liquid phase outlet 152 and the first heat exchanger liquid phase outlet 42 are combined through a pipeline and then are divided into two paths after passing through the third pump 110 and/or the second storage tank 120;

the two paths are: one passage is communicated with the second inlet 13 of the rectifying tower to form reflux, and the other passage is used for outputting wastewater components;

the sixth heat exchanger gas phase outlet 151 is used for outputting the non-condensable gas.

The sixth heat exchanger liquid phase outlet 152 and the first heat exchanger liquid phase outlet 42 are combined through a pipeline and then divided into two paths after passing through the third pump 110 and/or the second storage tank 120, and specifically, the following connection modes can be adopted:

the sixth heat exchanger liquid phase outlet 152 and the first heat exchanger liquid phase outlet 42 are combined through a pipeline, communicated through the third pump 110 and then divided into two passages;

alternatively, the sixth heat exchanger liquid phase outlet 152 and the first heat exchanger liquid phase outlet 42 are combined through a pipeline, communicated through the second storage tank 120, and then divided into two passages;

alternatively, the sixth heat exchanger liquid phase outlet 152 and the first heat exchanger liquid phase outlet 42 are combined through a pipeline, and then are communicated with the second storage tank 120 and the third pump 110 in sequence, and then are divided into two paths.

The first heat exchanger 40 may be a dividing wall heat exchanger, such as a shell and tube heat exchanger, with the first heat exchanger vapor outlet 41 in communication with the sixth heat exchanger 150 for condensing the incoming fluid and the first heat exchanger liquid outlet 42 for outputting the condensed liquid. The sixth heat exchanger 150 may be a dividing wall type heat exchanger, such as a shell-and-tube type heat exchanger, the sixth heat exchanger 150 is configured to further condense the introduced fluid, the liquid phase outlet 152 of the sixth heat exchanger is configured to output condensed liquid, and the condensed liquid may flow back to the rectifying tower for further rectification; the sixth heat exchanger gas phase outlet 151 is used for outputting non-condensable gas, and the non-condensable gas is discharged, so that the treatment effect of the system is further improved.

In a preferred fourth embodiment, as shown in fig. 7, the recovery system further comprises a sixth heat exchanger 150, the sixth heat exchanger 150 being provided with a sixth heat exchanger vapor phase outlet 151 and a sixth heat exchanger liquid phase outlet 152;

the second storage tank 120 is further provided with a second storage tank gas phase outlet 121;

the second storage tank gas-phase outlet 121 is communicated with a sixth heat exchanger 150, the sixth heat exchanger liquid-phase outlet 152 is communicated with the second storage tank 120, and the sixth heat exchanger gas-phase outlet 151 is used for outputting non-condensable gas.

The second tank 120 is used for gas-liquid separation, and the separated gas phase is discharged from a second tank gas phase outlet 121. The sixth heat exchanger 150 may be a dividing wall type heat exchanger, such as a shell-and-tube type heat exchanger, the sixth heat exchanger 150 is configured to further condense the introduced fluid, the liquid phase outlet 152 of the sixth heat exchanger is configured to output condensed liquid, and the condensed liquid may flow back to the rectifying tower for further rectification; the sixth heat exchanger gas phase outlet 151 is used for outputting non-condensable gas, and the non-condensable gas is discharged, so that the treatment effect of the system is further improved.

In a preferred second embodiment, as shown in fig. 4 and 5, the recovery system further comprises a fourth pump 130 and/or a third storage tank 140, the fourth pump 130 and/or the third storage tank 140 being provided on a path connecting the permeate side outlet 32 and the first inlet 12 of the rectification column. Specifically, the following connection means may be available:

the outlet 32 at the permeation side is communicated with the first inlet 12 of the rectifying tower through a fourth pump 130;

the outlet 32 at the permeation side is communicated with the first inlet 12 of the rectifying tower through a third storage tank 140;

the outlet 32 at the permeation side is communicated with the first inlet 12 of the rectifying tower through a third storage tank 140 and a fourth pump 130 in sequence;

the outlet 32 on the permeation side is communicated with the first inlet 12 of the rectifying tower through a fifth heat exchanger 100 and a fourth pump 130 in sequence;

the outlet 32 on the permeation side is communicated with the first inlet 12 of the rectifying tower through a fifth heat exchanger 100 and a third storage tank 140 in sequence;

the permeate side outlet 32 is in communication with the rectifier first inlet 12 via a fifth heat exchanger 100, a third storage tank 140, and a fourth pump 130 in that order.

The fourth pump 130 is used for pressurizing the introduced fluid and then refluxing the pressurized fluid to the rectifying tower. The third reservoir 140 is used to buffer and store the incoming fluid.

In a preferred third embodiment, as shown in fig. 6, the recovery system further comprises a seventh heat exchanger 160, the seventh heat exchanger 160 being provided with a seventh heat exchanger vapor outlet 161 and a seventh heat exchanger liquid outlet 162;

the fifth heating medium outlet 1012 is provided with a fifth heating medium gas phase outlet 10121 and a fifth heating medium liquid phase outlet 10122;

the fifth heat medium gas phase outlet 10121 is communicated with the seventh heat exchanger 160;

the seventh heat exchanger liquid phase outlet 162 and the fifth heating medium liquid phase outlet 10122 are combined through a pipeline and then communicated with the first inlet 12 of the rectifying tower; or, the seventh heat exchanger liquid phase outlet 162 and the fifth heat medium liquid phase outlet 10122 are combined through a pipeline, and then are communicated with the first inlet 12 of the rectifying tower after passing through the fourth pump 130 and/or the third storage tank 140;

the seventh heat exchanger gas phase outlet 161 is for outputting non-condensable gases.

The seventh heat exchanger liquid phase outlet 162 and the fifth heat medium liquid phase outlet 10122 are combined through a pipeline, and then communicated with the first inlet 12 of the rectifying tower after passing through the fourth pump 130 and/or the third storage tank 140, specifically, the following connection modes can be adopted:

the seventh heat exchanger liquid phase outlet 162 and the fifth heat medium liquid phase outlet 10122 are combined through a pipeline, then are communicated with the first inlet 12 of the rectifying tower after passing through the fourth pump 130;

the seventh heat exchanger liquid phase outlet 162 and the fifth heat medium liquid phase outlet 10122 are combined through a pipeline, then pass through the third storage tank 140 and are communicated with the first inlet 12 of the rectifying tower;

or, the seventh heat exchanger liquid phase outlet 162 and the fifth heat medium liquid phase outlet 10122 are combined through a pipeline, and then sequentially pass through the third storage tank 140 and the fourth pump 130, and then are communicated with the first inlet 12 of the rectifying tower.

The fifth heat exchanger 100 may be a dividing wall type heat exchanger, such as a shell-and-tube type heat exchanger, the fifth heat medium gas phase outlet 10121 is communicated with the seventh heat exchanger 160 for condensing the introduced fluid, and the fifth heat medium liquid phase outlet 10122 for outputting the condensed liquid. The seventh heat exchanger 160 may be a dividing wall type heat exchanger, such as a shell-and-tube type heat exchanger, the seventh heat exchanger 160 is used for further condensing the introduced fluid, the seventh heat exchanger liquid phase outlet 162 is used for outputting the condensed liquid, and the condensed liquid may flow back to the rectifying tower for further rectification; the seventh heat exchanger gas-phase outlet 161 is used for outputting non-condensable gas, and the non-condensable gas is discharged, so that the treatment effect of the system is further improved.

In a preferred fourth embodiment, as shown in fig. 7, the recovery system further comprises a seventh heat exchanger 160, the seventh heat exchanger 160 being provided with a seventh heat exchanger vapor outlet 161 and a seventh heat exchanger liquid outlet 162;

the third storage tank 140 is further provided with a third storage tank gas phase outlet 141;

the third tank gas phase outlet 141 is communicated with the seventh heat exchanger 160, the seventh heat exchanger liquid phase outlet 162 is communicated with the third tank 140, and the seventh heat exchanger gas phase outlet 161 is used for outputting non-condensable gas.

The third storage tank 140 is used for gas-liquid separation, and the separated gas phase is discharged from a third storage tank gas phase outlet 141. The seventh heat exchanger 160 may be a dividing wall type heat exchanger, such as a shell-and-tube type heat exchanger, the seventh heat exchanger 160 is used for further condensing the introduced fluid, the seventh heat exchanger liquid phase outlet 162 is used for outputting the condensed liquid, and the condensed liquid may flow back to the rectifying tower for further rectification; the seventh heat exchanger gas-phase outlet 161 is used for outputting non-condensable gas, and the non-condensable gas is discharged, so that the treatment effect of the system is further improved.

In a preferred embodiment, the recovery system further comprises a vacuum unit provided in the path of the first outlet 16 of the rectification column and/or in the permeate-side outlet 32.

The vacuum unit is arranged on the passage of the first outlet 16 of the rectifying tower, and specifically, the following connection modes can be provided:

the first heat exchanger 40 is in communication with the vacuum unit;

alternatively, the second reservoir 120 is in communication with a vacuum unit;

alternatively, the sixth heat exchanger gas-phase outlet 151 is communicated with a vacuum unit.

The vacuum unit is arranged on the path of the permeation side outlet 32, and specifically, the following connection modes can be adopted:

the zeolite membrane assembly 30 is in communication with a vacuum unit;

alternatively, the fifth heat exchanger 100 is in communication with a vacuum unit;

alternatively, the third reservoir 140 is in communication with a vacuum unit;

alternatively, the seventh heat exchanger gas-phase outlet 161 is communicated with a vacuum unit.

The vacuum unit is provided in various combinations in the passage of the rectifying tower first outlet 16 and the passage of the permeate-side outlet 32, and specifically, the following connection modes are possible:

the first heat exchanger 40 communicates with the vacuum unit, and the fifth heat exchanger 100 communicates with the vacuum unit;

alternatively, the second reservoir 120 is in communication with a vacuum unit, the third reservoir 140 is in communication with a vacuum unit, and so on.

The vacuum unit is used for maintaining the vacuum degree of the recovery system.

In a preferred embodiment, the recycling system further comprises a fourth storage tank 170 and a vacuum unit in communication, the vacuum unit and the fourth storage tank 170 being disposed in the path of the first outlet 16 of the rectification column.

The vacuum unit and the fourth storage tank 170 are disposed on the path of the first outlet 16 of the rectification column, and specifically, the following connection modes can be provided:

the first heat exchanger 40 is in communication with the vacuum unit via a fourth storage tank 170;

alternatively, the second reservoir 120 is in communication with the vacuum unit via a fourth reservoir 170;

alternatively, the sixth heat exchanger gas-phase outlet 151 communicates with the vacuum unit via the fourth storage tank 170.

The fourth storage tank 170 serves to stabilize the recovery system pressure (vacuum). In order to effectively control the working pressure, inert gas can be introduced, when the pressure is too low, the inert gas is supplemented to the recovery system, and the pressure is properly increased.

In a preferred embodiment, the recovery system further comprises a fifth reservoir 180 and a vacuum unit in communication, the vacuum unit and the fifth reservoir 180 being disposed in the path of the permeate side outlet 32.

The vacuum unit and the fifth storage tank 180 are arranged on the path of the permeation side outlet 32, and specifically, the following connection modes can be provided:

the zeolite membrane assembly 30 is in communication with the vacuum unit via a fifth storage tank 180;

alternatively, the fifth heat exchanger 100 is in communication with the vacuum unit via a fifth storage tank 180;

alternatively, the third reservoir 140 is in communication with the vacuum unit via a fifth reservoir 180;

alternatively, the seventh heat exchanger vapor outlet 161 is in communication with the vacuum unit via the fifth storage tank 180.

The fifth storage tank 180 serves to stabilize the recovery system pressure (vacuum). In order to effectively control the working pressure, inert gas can be introduced, when the pressure is too low, the inert gas is supplemented to the recovery system, and the pressure is properly increased.

The vacuum unit in each of the above embodiments may specifically be a vacuum pump.

Another embodiment of the present invention further provides a method for recovering N-methyl-2-pyrrolidone waste liquid, comprising the following steps: rectifying the N-methyl-2-pyrrolidone waste liquid by a rectifying tower:

obtaining an overhead stream from the top of the column; the tower top stream is subjected to heat exchange treatment and is condensed and divided into two parts: one part of the waste water flows back to the rectifying tower, and the other part of the waste water is a waste water component;

obtaining a bottom stream from the bottom of the column; the bottom stream is divided into two parts: one part of the heavy components flows back to the rectifying tower after heat exchange treatment, and the other part of the heavy components flows back to the rectifying tower;

a liquid phase stream extracted from a liquid collecting unit of the rectifying tower is pressurized and then divided into two parts: one part of the liquid phase stream is refluxed to the rectification column and the other part of the liquid phase stream is subjected to a zeolite membrane separation process to provide an N-methyl-2-pyrrolidone product stream and a permeate stream.

In the recovery method, a single rectifying tower and a zeolite membrane are used for separation treatment to complete purification of the N-methyl-2-pyrrolidone in the waste liquid, so that an electronic-grade product can be obtained, the process flow is short, the adaptability to the N-methyl-2-pyrrolidone waste liquid is high, the water content can be changed in a large range, the product quality is stable, and the operation is simple.

In a preferred embodiment, the waste N-methyl-2-pyrrolidone liquid is subjected to a heat exchange treatment with a product N-methyl-2-pyrrolidone stream provided by a zeolite membrane separation treatment to provide a cooled product N-methyl-2-pyrrolidone stream and a heated waste N-methyl-2-pyrrolidone liquid, and the heated waste N-methyl-2-pyrrolidone liquid is rectified by a rectifying tower.

The heat energy of the N-methyl-2-pyrrolidone product stream provided by zeolite membrane separation treatment is effectively utilized, and the energy consumption is saved.

In a preferred embodiment, the permeate stream provided by the zeolite membrane separation process is heat exchanged to provide a condensed permeate stream, or the permeate stream provided by the zeolite membrane separation process is heat exchanged and refluxed to the rectification column.

The penetrating fluid stream provided by the zeolite membrane separation treatment is condensed by heat exchange treatment, the steam pressure difference of the easily permeable components on the two sides of the zeolite membrane is increased, and the permeation flux is favorably improved, or further, the penetrating fluid stream provided by the condensed zeolite membrane separation treatment flows back to the rectifying tower, so that the treatment effect of the system is further improved.

In a preferred embodiment, the pressurized liquid phase stream is subjected to a heat exchange treatment and then to a zeolite membrane separation treatment; preferably, the temperature of the liquid phase stream after heat exchange treatment is 120-160 ℃, preferably 125-150 ℃, and further preferably 130-140 ℃.

And performing heat exchange treatment on the pressurized liquid phase stream to provide a heated liquid phase stream so as to increase the permeation flux of the zeolite membrane.

The zeolite membrane has larger permeation flux and more ideal separation coefficient when the temperature is in the numerical range, and is more favorable for dehydration. Too low a temperature may result in small permeation flux and poor dehydration effect; excessive temperatures can cause damage to the zeolite membrane and a reduced service life.

In a preferred embodiment, the zeolite membrane is a water-preferentially permeable zeolite membrane. The water in the stream permeates the water-preferentially permeable zeolite membrane as a permeate stream.

In a preferred embodiment, the absolute pressure at the top of the rectifying column is from 0.5kPa to 20kPa, preferably from 2kPa to 15kPa, and more preferably from 5kPa to 10 kPa. The pressure at the tower top is too low, the power consumption of a vacuum pump is too high, the condensation temperature is too low, and the cold energy consumption is too high; the pressure at the top of the tower is too high, the pressure at the bottom of the tower is too high, the energy required by reboiling the reboiler is large, the temperature is high, and a heating medium with higher temperature is required.

In a preferred embodiment, the zeolite membrane separation process conditions are: absolute pressure at the permeation side is less than or equal to 20kPa, and relative pressure (i.e. gauge pressure) at the retentate side is 0.1MPa to 1 MPa; the absolute pressure of the permeation side is preferably 0.5kPa to 5kPa, and the relative pressure (i.e. gauge pressure) of the retentate side is preferably 0.2MPa to 0.5 MPa; the absolute pressure on the permeate side is more preferably 1kPa to 3kPa, and the relative pressure (i.e., gauge pressure) on the retentate side is more preferably 0.3MPa to 0.4 MPa.

The operation pressure is in the range, the permeation flux and the separation coefficient are larger, the treatment capacity and the separation effect are better, and the overall cost is lower. The permeate side pressure is too high, the permeate flux is low, and the treatment capacity is influenced; the excessive pressure on the redundant side increases the power consumption, and the increase of the permeation flux is not obvious. The pressure of the permeation side is too low, the condensation temperature is too low, the condensation of the permeate is not facilitated, and the load of a vacuum pump is obviously increased; the pressure on the retentate side is too low, the raw material liquid may be partially vaporized, and the system cannot operate normally.

In a preferred embodiment, the relative pressure (i.e., gauge pressure) of the pressurized liquid phase stream is 0.2 to 1.2MPa, preferably 0.3 to 0.8MPa, and more preferably 0.5 to 0.6 MPa.

The relative pressure within the above numerical range is favorable for increasing the permeation flux of the zeolite membrane and for dehydration. The relative pressure lower than 0.2MPa may cause small permeation flux and poor dehydration effect; the permeation flux of the zeolite membrane with the relative pressure of more than 1.2Mpa is not obviously increased.

In a preferred embodiment, the overhead stream is condensed after being subjected to the heat exchange treatment and then is divided into two parts by a third pump and/or a second storage tank: one part of the waste water flows back to the rectifying tower, and the other part of the waste water is a waste water component.

The third pump is used for pressurizing the introduced fluid and then dividing the pressurized fluid into two parts, wherein one part outputs the wastewater component, and the other part reflows to the rectifying tower.

The second storage tank is used for buffering and storing the introduced fluid.

In a preferred embodiment, the overhead stream is heat exchanged to provide an overhead heat exchanged gas phase stream and an overhead heat exchanged liquid phase stream;

performing heat exchange treatment on the tower top heat exchange gas phase stream to provide a first gas phase stream and a first liquid phase stream;

the first liquid phase stream is mixed with the tower top heat exchange liquid phase stream and then divided into two parts; or the first liquid phase stream is mixed with the tower top heat exchange liquid phase stream and then is divided into two parts by a third pump and/or a second storage tank;

the two parts are as follows: one part of the waste water flows back to the rectifying tower, and the other part of the waste water is a waste water component;

the first gas phase stream is a non-condensable gas;

and the tower top heat exchange gas phase flow is subjected to heat exchange treatment, so that introduced fluid is further condensed, the condensed liquid can be further recycled, non-condensable gas is discharged, and the treatment effect is further improved.

In a preferred embodiment, the overhead stream is condensed by a heat exchange process and then passes through a second storage tank to provide a second storage tank vapor stream and a second storage tank liquid stream;

performing a heat exchange treatment on the second storage tank gas phase stream to provide a first gas phase stream and a first liquid phase stream;

refluxing the first liquid phase stream to a second storage tank, and mixing the first liquid phase stream with the second storage tank liquid phase stream;

the first gas phase stream is a non-condensable gas;

and the gas-phase stream of the second storage tank is subjected to heat exchange treatment, so that introduced fluid is further condensed, the condensed liquid can be further recycled, non-condensable gas is discharged, and the treatment effect of the system is further improved.

In a preferred embodiment, the permeate stream provided by the zeolite membrane separation process is condensed by heat exchange treatment, passed to a fourth pump and/or a third storage tank, and refluxed to the rectification column.

The fourth pump 130 is used for pressurizing the introduced fluid and then refluxing the pressurized fluid to the rectifying tower.

The third reservoir 140 is used to buffer and store the incoming fluid.

In a preferred embodiment, the permeate stream provided by the zeolite membrane separation process is subjected to a heat exchange process to provide a permeate gas phase stream and a permeate liquid phase stream;

subjecting the permeate vapor stream to a heat exchange process to provide a second vapor stream and a second liquid stream;

mixing the second liquid phase stream and the penetrating fluid liquid phase stream, introducing the mixture into a fourth pump and/or a third storage tank, and refluxing the mixture to the rectifying tower;

the second vapor phase stream is a non-condensable gas.

And the penetrating fluid gas-phase stream is subjected to heat exchange treatment, so that introduced fluid is further condensed, the condensed liquid can be further recycled, non-condensable gas is discharged, and the treatment effect of the system is further improved.

In a preferred embodiment, the permeate stream provided by the zeolite membrane separation process is condensed by a heat exchange process and then passes through a third storage tank to provide a third storage tank vapor stream and a third storage tank liquid stream;

performing a heat exchange treatment on the third storage tank gas phase stream to provide a second gas phase stream and a second liquid phase stream;

the second liquid phase stream flows back to the third storage tank and is mixed with the liquid phase stream of the third storage tank;

the second vapor phase stream is a non-condensable gas.

And the gas-phase stream of the third storage tank is subjected to heat exchange treatment, so that introduced fluid is further condensed, the condensed liquid can be further recycled, non-condensable gas is discharged, and the treatment effect of the system is further improved.

In a preferred embodiment, the second reservoir is provided with a vacuum via the fourth reservoir and the vacuum unit, and the non-condensable gasses are obtained from an outlet of the vacuum unit. The fourth storage tank is used for stabilizing the pressure (vacuum degree) of the recovery system.

In a preferred embodiment, the third reservoir is provided with a vacuum via the fifth reservoir and the vacuum unit, and the non-condensable gasses are obtained from an outlet of the vacuum unit. The fifth storage tank is used for stabilizing the pressure (vacuum degree) of the recovery system.

The vacuum unit is used for maintaining the vacuum degree of the recovery system, can be a vacuum pump, and is used for extracting air from the unit to be extracted to obtain vacuum.

The above-mentioned non-condensable gas means gas in which dissolved air in the material, air leaked from the joint into the system, etc. cannot be condensed under the operating conditions.

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