KR101912190B1 - Hybrid type mixture separating apparatus - Google Patents

Abstract

The present invention relates to a mixed liquid separator for use in a chemical separation process such as a gas / liquid or a liquid / liquid mixture in the form of a distillation column equipped with a reboiler, wherein a mixed liquid discharge port (111) A housing 110 in which an inlet 112 is formed; A mixed liquid conduit 120 connecting the mixed liquid outlet 111 and the mixed liquid inlet 112; A separator 130 positioned below the mixed liquid discharge port 111 in the housing 110 to allow the mixed liquid supplied to the upper portion of the housing 110 to flow into the mixed liquid discharge port 111; A heater (110) disposed below the separator (130) in the housing (110) for separating the gas to be separated from the mixed liquid by providing heat to the mixed liquid provided to the mixed liquid inlet (112) And the housing 110 has a residual liquid outlet 113 formed at a height between the separator 130 and the heater 140 to discharge the separated residual liquid, 130) is provided with a gas discharge port (131) for discharging the gas to be separated separated from the heater (140) without flowing the mixed liquid.

Description

[0001] The present invention relates to a hybrid type mixture separating apparatus,

The present invention relates to a hybrid type mixed liquid separator, and more particularly, to a mixed liquid separator for use in a chemical / liquid separation or a liquid / liquid mixture, .

The prior art chemical process for gas / liquid or liquid / liquid separation uses a distillation type tower, and a heating type reboiling device is provided in the distillation tower to heat the mixture to heat. Separate.

Generally, reboilering equipment is divided into several types and is divided into several types: Internal Reboiler, Kettle Reboiler, Vertical Thermosyphon Reboiler, and Horizontal Thermosyphon There is a Horizontal Thermosyphon Reboiler.

The internally boiler is the simplest type of equipment, with a hot-wire coil that can heat directly to the bottom of the tower. The gas evaporated by the heat generated at the bottom of the tower moves to the top of the tower, It is a way to move down through the tower. The biggest disadvantage of the internally boiler is the size of the distillation column. When the size of the distillation column is small, the installation capacity of the reboiler is limited, and the bubbles generated due to the rusting may rise to the inside of the distillation column Plate-pin type hot-wire coil is mainly used to reduce installation size of reboiler. In addition, the internal reboiler has the disadvantage that the amount of heat transferred per unit volume is very small.

Kettle boilers are the most widely used type because they have the best heat transfer efficiency among the boiler types. However, the liquid scale and the gas can interfere with each other to cause process abnormalities, and the solid scale that can be precipitated through long- There is a problem that it can be stacked inside the boiler.

The vertical thermosyphon reboiler has the advantage that the heating heat line is installed outside the distillation column and has better heat transfer efficiency and less solid fouling than the kettle type. However, there is an additional advantage that the reboiler is installed outside the distillation column There is a drawback in that a separate space is required, and there is a disadvantage that the material is overused due to the amount of the circulating fluid.

The horizontal type thermosyphon reboiler has a structure in which the horizontal type uses a heat exchanger, and has a lower headroom and natural circulation compared to a vertical thermosyphony boiler. However, there is a problem in fouling And the heat transfer effect is uncertain.

In recent years, as global warming and air pollution have become more serious, technology for suppressing the release of carbon dioxide has been actively developed. Especially, a lot of studies are being conducted to efficiently capture carbon dioxide emitted from a thermal power plant or a boiler facility .

Recently, it has been widely known that a chemical absorption method using an absorption liquid is suitable for capturing a large amount of carbon dioxide to capture carbon dioxide. According to the chemical absorption method, carbon dioxide emitted from a thermal power plant or a boiler facility is absorbed into an absorption liquid in an absorption tower, and a saturated absorption liquid which absorbs carbon dioxide is heated in a regeneration tower to separate carbon dioxide from an absorption liquid.

The regeneration tower is equipped with a reboiler for heating the absorption liquid as an energy source for regeneration. The reboiler heats up the absorption liquid to a regenerable temperature, separating the gas contained in the absorption liquid, and most kettle type reboilers are used for space saving and cost saving.

However, during the operation of the regeneration tower, the heat stable salt problem that may occur during long-term operation with the amine absorption liquid and the generation path of the carbon dioxide and steam dissolved in the liquid are overlapped with the rich amine (liquid) Bubbles may be generated, and level control problems may occur.

Japanese Patent Application Laid-Open No. 10-2015-0084375 (published on July 21, 2015)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art, and it is an object of the present invention to provide a hybrid type in which the advantages of various types of reboilers are mixed, And to provide a hybrid type mixed liquid separation apparatus.

Another object of the present invention is to provide a hybrid type mixed liquid separating apparatus capable of improving the heat transfer efficiency in the process of separating the mixed liquid and easily controlling the liquid surface level fluctuated by boiling.

According to an aspect of the present invention, there is provided a mixed liquid separator according to an embodiment of the present invention, comprising: a housing having a mixed liquid discharge port formed at an upper portion thereof and a mixed liquid inlet port formed at a lower portion thereof; A mixed solution conduit connecting the mixed solution outlet and the mixed solution inlet; A separator disposed below the mixed liquid outlet in the housing to allow the mixed liquid supplied to the upper portion of the housing to flow to the mixed liquid outlet; And a heater located below the separator in the housing and separating the gas to be separated from the mixed solution by providing heat to the mixed solution supplied to the mixed solution inlet and generating a separated residual solution, And a residual gas discharge port formed at a height between the heaters to discharge the residual residual liquid, wherein the separator has a gas discharge port for discharging the gas to be separated separated from the heater without the mixed liquid flowing therein .

Preferably, a plurality of the mixed liquid discharge ports are formed at positions spaced apart from the gas discharge port so that the level of the mixed liquid is positioned below the gas discharge port at the upper part of the separator.

Preferably, the separator comprises: a mounting plate coupled to the housing, the mixing plate having a through hole through which the gas to be separated passes; A body having the gas outlet at a predetermined height from the mounting plate; And a roof covering the gas outlet so as to prevent the mixed liquid from flowing.

More preferably, the mounting plate has an upper surface inclined so that the mixed liquid flows toward the mixed liquid discharge port.

More preferably, the loop has an upper surface that is inclined so that the mixed liquid is not accumulated.

Preferably, the highest point of the mixed liquid discharge port is located below the lowest point of the gas discharge port.

Preferably, the gas discharge port is formed in a direction different from the mixed liquid discharge port.

Preferably, a plurality of the remaining liquid discharge ports are formed in the housing.

Preferably, the mixed liquid conduit or the lower portion of the housing further includes a salt separator for separating the solid salt contained in the mixed liquid by gravity.

According to another aspect of the present invention, there is provided a mixed liquid separator comprising: a mixed liquid tank having a mixed liquid outlet formed at a lower portion thereof and a gas inlet formed at an upper portion thereof; A housing having a gas outlet formed at an upper portion thereof and a mixed liquid inlet formed at a lower portion thereof; A gas conduit connecting the gas outlet and the gas inlet; A mixed solution conduit connecting the mixed solution outlet and the mixed solution inlet; And a heater disposed at an upper portion of the mixed liquid inlet in the housing to heat the mixed liquid supplied to the lower portion of the housing to separate the gas to be separated by the mixed liquid and to generate a separated residual liquid, And a residual liquid discharge port formed at a height between the discharge port and the heater for discharging the separated residual liquid.

Preferably, the mixed liquid tank further includes a gas outlet cover for covering the gas outlet so that the mixed liquid can not flow into the gas outlet.

The mixed liquor tank or the mixed liquor conduit may further include a salt separator for separating the solid salt contained in the mixed liquor by gravity.

Preferably, the residual liquid discharge port allows the separation target gas separated from the mixed liquid to be discharged directly from the housing, thereby suppressing the occurrence of a side reaction by heat.

Preferably, the heater has a flow path for allowing the mixed solution supplied to the mixed solution inlet to reach the residual solution discharge port via the heater.

Preferably, the residual liquid conduit is connected to the residual liquid outlet port; And a level sensor for measuring the level of the residual liquid in the residual liquid conduit. More preferably, the level of the mixed liquid in the housing is controlled through the level of the residual liquid in the residual liquid conduit .

Preferably, the height from the upper portion of the heater to the outlet for the residual liquid is a height required to complete the separation of the separation target gas from the mixed liquid.

Preferably, the gas outlet is formed at a position higher than the residual liquid outlet.

A mixed liquid separating apparatus according to the present invention is characterized in that a heater is disposed in a housing and a gas-liquid separator is physically provided so that the mixed liquid does not come into contact with the gas separated when the mixed liquid falls due to gravity, The mixed liquid can be stably separated by separating the liquid and gas passages from each other at the time of separating the mixed liquid, and it is possible to enhance the heat transfer efficiency and control the liquid surface level easily .

The present invention also includes a mixed liquid storage tank in which a mixed liquid is stored, a mixed liquid stored in the mixed liquid storage tank and a housing connected to the piping system so that gas separated by the heater can be moved by natural circulation Thus, the liquid and gas passages can be separated from each other without the need for a separate gas-liquid separator, so that the mixed liquid can be stably separated, the heat transfer efficiency can be enhanced, and the liquid surface level can be easily controlled.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall cross-sectional view of a mixed liquid separator according to a first embodiment of the present invention;
FIG. 2 is a cross-sectional view of a mixed liquid separator according to a first embodiment of the present invention,
FIGS. 3 to 5 are views showing another modification of the mixed liquid separating apparatus according to the first embodiment of the present invention. FIG.
FIG. 6 is an overall cross-sectional view of a mixed liquid separation apparatus according to a second embodiment of the present invention; FIG.

The specific structure or functional description presented in the embodiment of the present invention is merely illustrative for the purpose of illustrating an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention can be implemented in various forms. And should not be construed as limited to the embodiments described herein, but should be understood to include all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In the present invention, the term "mixed liquid" means a gas / liquid mixture or a liquid / liquid mixture having a different boiling point. For example, the gas / liquid mixture may be an absorbent that absorbs carbon dioxide

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, and the same components will be denoted by the same reference numerals.

First Embodiment

FIG. 1 is an overall cross-sectional view of a mixed liquid separator according to a first embodiment of the present invention, and FIG. 2 is an enlarged cross-sectional view of a mixed liquid separator according to the first embodiment of the present invention.

As illustrated in FIGS. 1 and 2, the mixed liquid separating apparatus according to the first embodiment includes a vertical column-shaped housing 110, and at the upper end of the housing 110, The mixed liquid supply unit 10 and the rectification unit 20 are disposed sequentially from the upper part of the inner side of the rectifying unit 20 and the heater 140 is limitedly separated by the separator 130, do.

The mixed liquid supply unit 10 may include a mixed liquid supply line 11 and a mixed liquid supply unit 12 and may have a multi-stage structure. In this embodiment, two mixed liquid supply units 10 are disposed between the rectified unit 20 .

The mixed liquid supply line 11 receives the mixed liquid from the absorption tower (not shown) or the condensed water from the condenser (not shown) or the heat exchanger (not shown), and the mixed liquid supplied to the mixed liquid supply line 11 and / Or the condensed water to the mixed liquid feeder (12).

The mixed liquid supplier 12 supplies the mixed liquid and / or the condensed water supplied from the mixed liquid supply line 11 into the housing 110 and the mixed liquid and / or the condensed water supplied through the mixed liquid supplier 12 are self- 110).

Reference numeral 13 denotes a fixed plate for fixing the mixed liquid feeder 12 to the housing.

The rectifying section 20 is for uniformly rectifying the flow of the mixed liquid and / or the condensed water, and may be formed by twisting an elongated wire into an irregular shape, or may be provided by a foam plastic having a large gap, It is not.

The rectifying unit 20 may be configured in the same manner as the mixed liquid supplying unit 10, and in the present embodiment, two rectifying units 20 are provided below the respective mixed liquid supplying units 10, respectively.

The separator 130 has a gas outlet 132a formed on the side thereof to restrictively separate the space between the rectifier 20 and the heater 140 located at the lowermost end, The mixed liquid in the upper space can not be directly transferred to the heater 140 through the separator 130. [

More specifically, the separator 130 includes a mounting plate 131 coupled to the housing 110 and having a through hole 131a through which the mixed gas flows to the mixed liquid outlet 111, A body 132 having a gas outlet 132a at a predetermined height from the gas outlet 131 and a roof 133 covering the gas outlet 132a to prevent the mixed liquid from flowing into the gas outlet 132a.

A plurality of gas outlets 132a may be formed in the body 132. The direction of the gas outlets 132a is preferably formed in a direction different from that of the mixed liquid outlets 111. [

The heater 140 is disposed at a lower portion of the separator 130 to provide heat to the mixed liquid. The heated mixed liquid evaporates in the space where the heater 140 is located, and a residual liquid is generated. The separated gas moves upward through the separator 130 and is discharged to the outside through the exhaust unit 101.

The housing 110 has a mixed liquid outlet 111 positioned between the rectifying unit 20 and the separator 130 positioned at the lowest position and a mixed liquid inlet 112 formed at a lower portion where the heater 140 is disposed, 111 and the mixed solution inlet 112 are connected by the mixed solution conduit 120.

The housing 110 is formed at a height between the separator 130 and the heater 140 to form a residue liquid outlet 113 through which the residual liquid separated from the mixture liquid can be discharged, 113 are located below the gas outlet 132a of the separator 130. The residual liquid outlet 113 may be connected to the residual liquid conduit 150 to discharge the residual liquid to the outside.

3, the housing 110 may be provided with a plurality of mixed solution outlets 111. At this time, the highest point of the mixed solution outlets 111 is located below the lowest point of the gas outlets 132a at a distance h1 . Therefore, the mixed liquid on the upper portion of the separator 130 can not be moved to the lower portion of the separator 130 through the gas outlet 132a, and the mixed liquid can be discharged smoothly through the plurality of mixed liquid outlets 111.

4, the mounting plate 231 of the separator 230 is fixed to the housing 110 with an inclination. At this time, the mixed liquid discharge port 111 is positioned at the lower end of the inclined surface of the mounting plate 231 So that the mixed liquid can be smoothly discharged along the mixed liquid conduit 120.

The loop 223 provided on the separator 230 has a sloped upper surface to prevent the mixed liquid supplied from the upper portion from sticking to the upper surface of the loop 223.

5, in the mixed liquid conduit 120 connected to the mixed liquid inlet 112 of the housing 110, a solid salt contained in the mixed liquid may be separated by gravity, And a valve 161 capable of being opened and closed can be provided at the front end of the salt separator 160.

A plurality of residual liquid discharge ports 113 may be provided in the housing 110. It is preferable that gas separated from the mixed liquid is discharged directly from the housing 110 to suppress side reactions caused by heat.

The mixed liquid supplied through the mixed liquid inlet 112 in the lower portion of the housing 110 preferably has a flow capable of reaching the residual liquid outlet 113 via the heater 140. For example, May be provided by a heat line that generates heat by receiving a current. In this case, the flow of the mixed liquid may be guided through a proper arrangement of the heat lines in a predetermined direction.

The water level sensor 151 for measuring the level of the separated residual liquid may be provided in the residual liquid conduit 150 connected to the residual liquid outlet 113. The level of the mixed liquid in the housing 110 may be measured by a water level sensor 151 The residual liquid in conduit 150 can be controlled through the level of the residual liquid.

The height h2 from the upper portion of the heater 140 to the residual liquid outlet 113 can be determined by the height required to complete the separation of the gas to be separated from the mixed liquid.

Second Embodiment

FIG. 6 is an entire cross-sectional view of the mixed liquid separating apparatus according to the second embodiment of the present invention. The same reference numerals are used for the same components as those in the first embodiment, and a duplicate description will be omitted.

As shown in FIG. 6, the mixed liquid separator according to the second embodiment includes a mixer tank 310 in the form of a vertical column, a heater 350, and a housing (not shown) The mixed liquid tank 310 is provided at its upper end with an exhaust part 301 for discharging gas to the outside and a mixed liquid discharge port 311 formed at a lower part thereof and a gas inlet port 312 formed at a side end thereof do.

The mixed liquid tank 310 may be provided with a mixture liquid supply unit 10 and a rectification unit 20 at the upper end of the gas inlet 312. The mixed liquid supply unit 10 and the rectification unit 20 may be similar to the first embodiment (Not shown), or the condensate is supplied from a condenser (not shown) or a heat exchanger (not shown) and is stored under the mixed liquid tank 310.

The housing 320 has a gas outlet 321 formed at an upper portion thereof and a mixed liquid inlet 322 at a lower portion thereof.

Preferably, the gas outlet 321 is provided at the uppermost end of the housing 320, so that the gas generated in the housing 320 can be prevented from remaining on the upper portion.

The gas inlet 312 of the mixed liquid tank 310 and the gas outlet 321 of the housing 320 are connected by the gas conduit 330 and the mixed liquid outlet 311 of the mixed liquid tank 310 and the gas outlet 321 of the housing 320 The mixed solution inlet 322 is connected by a mixed solution conduit 340.

A heater 350 is provided in the housing 320 to provide heat to the mixed liquid supplied through the mixed liquid inlet 322 located at the upper portion of the mixed liquid inlet 322. The heated mixed liquid is supplied into the housing 320 The gas is evaporated and a residual liquid is generated. The separated gas moves to the upper part of the mixed liquid tank 310 along the gas conduit 330 and is discharged to the outside through the exhaust part 101.

The housing 320 is disposed at a height between the gas outlet 321 and the heater 350, and a residue liquid outlet 323 through which the separated residual liquid is discharged is formed.

The gas discharge port cover 313 covering the gas discharge port 321 of the mixed liquid tank 310 is provided at the upper end of the gas inlet port 312 of the mixed liquid tank 310 so that the mixed liquid of the mixed liquid tank 310 flows into the gas discharge port 310. [ (321).

It is preferable that the mixed liquid supplied through the mixed liquid inlet 322 under the housing 320 has a flow capable of reaching the residual liquid outlet 323 via the heater 350. For example, The flow of the mixed liquid may be guided in a predetermined direction by appropriately arranging the heat lines.

A plurality of residual liquid discharge ports 323 may be provided in the housing 320 and it is preferable that gas separated from the mixed liquid is discharged directly from the housing 320 to suppress side reactions caused by heat.

The salt separator 370 may be added to the mixed liquid conduit 340 connected to the mixed liquid inlet 322 of the housing 320. The salt separator 370 may separate the solid salt contained in the mixed liquid by gravity And a valve 161 that can be opened and closed may be provided at the front end of the salt separator 370.

The water level sensor 361 for measuring the level of the separated residual liquid may be provided in the residual liquid conduit 360 connected to the residual liquid outlet port 323. The water level of the mixed liquid in the housing 320 may be measured by a water level sensor 361 The control can be performed through the level of the residual liquid in the residual liquid conduit 360 detected in the residual liquid conduit 360.

The height h3 from the upper portion of the heater 350 to the residual liquid discharge port 323 can be determined by the height required to complete the separation of the gas to be separated from the mixed liquid.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be apparent to those of ordinary skill in the art. While the embodiments have been described in order to facilitate understanding, it is to be understood that the embodiments may be combined within a range compatible with each other.

10: Mixed liquid supply part 20:
101, 301: exhaust part 110, 320: housing
111, 311: Mixed liquid outlet 112: Mixed liquid inlet
113: Residual liquid outlet port 120, 340: Mixed liquid conduit
130, 230: separator 131, 231: mounting plate
131a: Through hole 132: Body
132a: gas outlet 133, 233: loop
140, 350: heater 150: residual liquid conduit
151, 361: Water level sensor 160: Salt separation unit
310: Mixed liquid tank 311: Mixed liquid outlet
312: gas inlet 313: gas outlet cover
321: Gas outlet port 322: Mixed liquid inlet
323: Residual liquid outlet

Claims (18)

delete delete delete delete delete delete delete delete delete A mixed liquid tank in which a mixed liquid discharge port is formed in a lower portion and a gas inlet port is formed in an upper portion;
A housing in which a gas outlet is formed at the uppermost end and a mixed liquid inlet is formed at the lower center so that residual gas is not generated;
A gas conduit connecting the gas outlet and the gas inlet;
A mixed solution conduit connecting the mixed solution outlet and the mixed solution inlet;
And a heater disposed at an upper portion of the mixed liquid inlet in the housing to heat the mixed liquid supplied to the lower portion of the housing to separate the gas to be separated into the mixed liquid and generate a separated residual liquid,
The housing is provided with a residue liquid outlet formed at a height between the gas outlet and the heater and through which the separated residue liquid is discharged so that the mixed liquid stored in the mixed liquid tank and the gas separated by the heater are moved by natural circulation Liquid separation device. 11. The method of claim 10,
Further comprising a gas outlet cover covering the gas outlet so that the mixed liquid can not be introduced into the gas outlet, into the mixed liquid tank. 11. The method of claim 10,
And a salt separator for separating the solid salt contained in the mixed liquid by gravity at a lower portion of the mixed liquid tank or the mixed liquid tank. ◈ Claim 13 is abandoned due to registration fee. 11. The method of claim 10,
Wherein the separation liquid outlet allows the separation target gas separated from the mixture liquid to be discharged directly from the housing, thereby suppressing the side reaction by heat. 11. The method of claim 10,
Wherein the heater has a flow path for allowing the mixed liquid supplied to the mixed liquid inlet to reach the residual liquid outlet via the heater. 11. The method of claim 10,
A residual liquid conduit connected to the residual liquid outlet;
And a water level sensor for measuring the level of the residual liquid in the residual liquid conduit. ◈ Claim 16 is abandoned due to registration fee. 16. The method of claim 15,
And the level of the mixed liquid in the housing is controlled through the level of the residual liquid in the residual liquid conduit. ◈ Claim 17 is abandoned due to registration fee. 11. The method of claim 10,
Wherein the height from the upper portion of the heater to the outlet of the residual liquid is a height necessary to complete the separation of the separation target gas from the mixture liquid. ◈ Claim 18 is abandoned due to registration fee. 11. The method of claim 10,
And the gas discharge port is formed at a position higher than the residual liquid discharge port.

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