KR20220139661A - Supercritical device comprising a mass flow meter - Google Patents

Abstract

According to an embodiment of the present invention, a supercritical device comprising a mass flowmeter is provided to obtain an accurate extraction end timing by predicting an extraction yield using the mass flowmeter. A supercritical device including a mass flowmeter includes: a storage tank for storing carbon dioxide, which is a supercritical solvent; an extractor connected to the storage tank to extract a specific substance as a sample and the supercritical solvent are supplied therein and react with each other; a pump disposed between the storage tank and the extractor to supply the supercritical solvent from the storage tank to the extractor; a separator separating the specific substance extracted through the extractor from the supercritical solvent and discharging only the specific substance; and a controller controlling the flow rate of the pump based on information received from mass flowmeters installed in front and rear of the extractor.

Description

Supercritical device comprising a mass flow meter

The present invention relates to a supercritical device including a mass flow meter capable of predicting an extraction yield using a mass flow meter to clearly determine an extraction end time.

Supercritical fluid extraction technology (Supercritical Fluid Extraction Technology) is one of separation technologies, and is a technology for extracting and refining a specific substance using a fluid having a critical temperature and a critical pressure or higher. More specifically, the supercritical fluid is a state of matter that exists above a critical point, that is, a critical temperature, and a critical pressure, and has intermediate properties between a gas and a liquid. A fluid having a density corresponding to that of a liquid and a permeability corresponding to that of a gas.

Since the density of the supercritical fluid changes greatly even with minute temperature and pressure changes, the degree of dissolution can be easily controlled, and also has unique characteristics different from those of gases and liquids. More specifically, the supercritical fluid is a liquid in terms of dissolution related to the interaction between the solvent and the solute molecules, and the density closely related to the ability to separate the solute from the matrix. Characteristics, high diffusivity, low surface tension, etc., which are related to substrate permeability, indicate the properties of a gas. Carbon dioxide in the supercritical fluid is widely used as an extraction and purification solvent due to its low critical temperature and pressure to make it supercritical compared to materials, it is harmless to the human body, environmentally friendly, and inexpensive in terms of cost.

However, when extracting a sample from the raw material charged in the extractor, there is a problem in that the amount of sample is extracted at the beginning of the extraction process, but the amount of the sample included in the raw material decreases over time and the extraction yield is lowered. In addition, even though the extraction yield of the sample is low, the amount of the supercritical solvent supplied to the extractor by the high-pressure pump is the same, and there are problems in that the supercritical solvent is wasted and the extraction end time is not accurately known.

It is an object of the present invention to provide a supercritical device including a mass flow meter that can clearly identify an extraction end point by predicting an extraction yield using a mass flow meter.

It is an object of the present invention to provide a supercritical device including a plurality of extractors capable of reducing the time for extracting a specific substance.

According to an embodiment of the present invention, a supercritical device including a mass flow meter is provided. A supercritical device including a mass flow meter includes a storage tank for storing carbon dioxide, which is a supercritical solvent, an extractor that is connected to the storage tank and a sample and a supercritical solvent are supplied therein to perform extraction of a specific substance as they react with each other, the A pump disposed between the storage tank and the extractor to supply a supercritical solvent from the storage tank to the extractor, a separator for separating a specific substance extracted through the extractor and the supercritical solvent to discharge only a specific substance, and a front end of the extractor and a controller for controlling the flow rate of the pump based on information received from mass flow meters installed at the rear end.

According to an example, the controller is configured to control the sample extracted by the extractor based on a difference in flow rate values received from each of the first mass flow meter disposed at the front end of the extractor and the second mass flow meter disposed at the rear end of the extractor. Determine the amount dissolved in the critical solvent.

As an example, when the difference between the flow rate values at the front end and the rear end of the extractor is smaller than a preset first set value, the controller stops the driving of the pump.

In one example, the controller notifies the user of the need to replace the sample loaded in the extractor after stopping the operation of the pump.

By way of example, when the difference between the flow rate values at the front end and the rear end of the extractor is equal to or greater than the first set value and is smaller than the second set value, the controller controls the difference between the flow rate value and the supercritical solvent supplied by the pump. Reduce the flow rate of the pump based on a table in which the relationship between the amounts of

In one example, the extractor includes a first extractor and a second extractor, a first inlet line through which the supercritical solvent is injected into the first extractor, and a second inlet line through which the supercritical solvent is injected into the second extractor. , a first discharge line for transferring the mixture discharged from the first extractor to the multi-separator, a second discharge line for transferring the mixture discharged from the second extractor to the multi-separator, and the second extractor from the first extractor is provided to a first recovery line through which the supercritical solvent is introduced and a second recovery line through which a supercritical solvent is introduced from the second extractor to the first extractor, and the controller is any one of the first extractor and the second extractor Control the valves on the lines to provide supercritical solvent to one extractor.

In one example, when the difference between the flow rate values of the front end and the rear end of the first extractor among the first extractor and the second extractor is smaller than a preset first set value, the controller is configured to control the first phase of the first inlet line. Close the valve and open the second valve on the second inlet line to control the supercritical solvent to be supplied to the second extractor.

According to an example, when the difference between the flow rate values of the front end and the rear end of the first extractor among the first extractor and the second extractor is equal to or greater than a preset first set value and is smaller than the second set value, the controller may 1 Reduce the flow rate of the pump while supplying the supercritical solvent through the inlet line.

In one example, the controller controls the flow rate of the supercritical solvent supplied to the first inlet line and the second inlet line according to the difference between the flow rate values of the front and rear ends of the first extractor and the second extractor, respectively. do.

In one example, the mass flow meters include a first mass flow meter, a second mass flow meter and a third mass flow meter, wherein the first mass flow meter comprises a point where the first inlet line and the second return line meet and the second mass flow meter. disposed between one extractor, wherein the second mass flow meter is disposed between the second extractor and a point where the second inlet line and the first return line meet and the third mass flow meter is disposed between the first extractor and the second It is placed at the rear end of the extractor.

In one example, the first mass flow meter measures the flow rate of the supercritical solvent supplied to the first extractor from the second recovery line and the flow rate of the supercritical solvent supplied to the first extractor through the first inlet line. measuring, and the second mass flow meter measures the flow rate of the supercritical solvent supplied to the second extractor from the first recovery line and the flow rate of the supercritical solvent supplied to the second extractor through the second inlet line .

In one example, the extractor includes a cover that is opened for sample replacement and a sensor that detects whether the cover is opened, and the controller stops driving the pump when the cover is opened by the sensor. and close the valve disposed on the line through which the supercritical solvent is provided to the extractor.

According to an embodiment of the present invention, the controller may notify the user that the sample loaded in the extractor needs to be replaced after stopping the operation of the high-pressure pump. The user can accurately recognize the fact that the extraction process has been completed by the signal output by the controller (signal that the sample needs to be replaced).

According to an embodiment of the present invention, the controller may control the flow rate of the high-pressure pump based on the relationship between the difference between the flow rate values measured by the second mass flow meter and the first mass flow meter and the amount of the supercritical solvent supplied by the high-pressure pump. have. Accordingly, excessive supply of the supercritical solvent may be prevented, thereby improving the economic feasibility of the extraction process.

1 is a diagram illustrating a supercritical device including a mass flow meter according to an embodiment of the present invention.
2 is a diagram for explaining a function of a controller according to an embodiment of the present invention.
3 is a diagram illustrating a part of a supercritical device including a mass flow meter according to another embodiment of the present invention.
4 is a diagram illustrating a part of a supercritical device including a mass flow meter according to another embodiment of the present invention.

Advantages and features of the present invention, and a method for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only this embodiment serves to complete the disclosure of the present invention, and to obtain common knowledge in the technical field to which the present invention pertains. It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Terms such as "...unit", "...unit", "...module", etc. described in the specification mean a unit that processes at least one function or operation, which is hardware or software or hardware and software. It can be implemented as a combination.

In addition, the reason that the names of the components are divided into the first, the second, etc. in the present specification is to distinguish the names of the components in the same relationship, and the order is not necessarily limited in the following description.

The detailed description is illustrative of the invention. In addition, the above description shows and describes preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications are possible within the scope of the concept of the invention disclosed herein, the scope equivalent to the described disclosure, and/or within the scope of skill or knowledge in the art. The described embodiment describes the best state for implementing the technical idea of the present invention, and various changes required in the specific application field and use of the present invention are possible. Accordingly, the detailed description of the present invention is not intended to limit the present invention to the disclosed embodiments. Also, the appended claims should be construed as including other embodiments.

1 is a diagram illustrating a supercritical device including a mass flow meter according to an embodiment of the present invention.

Referring to FIG. 1 , the supercritical device 1 includes a storage tank 100 , a high-pressure pump 200 , a first heat exchanger 300 , an extractor 400 , a second heat exchanger 500 , and a separator 600 . may include. The supercritical device 1 may refer to a device for extracting a specific substance from a sample using a supercritical solvent and separating the specific substance from the supercritical solvent. The supercritical solvent may mean that when a critical pressure or a critical temperature is applied to a supercritical target material, ie, a material such as carbon dioxide, water, alcohol, or helium, it becomes a fluid in a special situation under a high temperature and high pressure state. In an embodiment of the present invention, the supercritical material may be carbon dioxide.

The storage tank 100 may store carbon dioxide. The storage tank 100 may store idealized carbon as a solvent in a stable liquid state. The solvent discharged from the storage tank 100 may be liquefied in the first condenser 150 , and the liquefied solvent may be introduced into the high-pressure pump 200 .

The high-pressure pump 200 may increase the pressure of the solvent, and may flow the solvent whose pressure is increased to the first heat exchanger 300 . The first heat exchanger 300 may heat the solvent that has passed through the high-pressure pump 200 . The first heat exchanger 300 may use various means for increasing the temperature of the solvent by exchanging heat with the outside, and more specifically, it may convert the solvent into a supercritical solvent.

The supercritical solvent converted to the supercritical state by the first heat exchanger 300 may be transferred to the extractor 400 . The extractor 400 may extract a specific substance as a sample and a supercritical solvent are supplied therein and react with each other. That is, the extractor 400 may serve to extract a specific substance in the sample using a supercritical solvent. The pressure inside the extractor 400 may be 300 bar to 500 bar. In order to satisfy the pressure of the extractor 400 , the high-pressure pump 200 may transfer the supercritical solvent in a high-pressure state to the extractor 400 .

A raw material may be charged in the extractor 400 . The extractor 400 may include a cover or a door for introducing the raw material therein and for discharging the raw material from which the sample is extracted. The extractor 400 may be provided with a sensor 410 for detecting whether the cover is opened. The sensor 410 may transmit a message informing the controller (not shown) when the cover is opened.

Mass flow meters 20 and 30 may be disposed at the front and rear ends of the extractor 400 . The mass flow meters 20 and 30 may determine the flow rate of the supercritical solvent and the amount of the raw material dissolved in the supercritical solvent during the extraction process. The mass flow meters 20 and 30 may include a first mass flow meter 20 disposed at a front end of the extractor 400 and a second mass flow meter 30 disposed at a rear end of the extractor 400 . The first mass flow meter 20 may measure the flow rate of the supercritical solvent supplied to the extractor 400 , and the second mass flow meter 30 may measure the flow rate of the supercritical solvent flowing from the extractor 400 to the separator 600 . flow can be measured. Specifically, in the second mass flow meter 30 , the flow rate of the supercritical solvent discharged from the extractor 400 may include the amount of the raw material dissolved in the supercritical solvent during the extraction process. That is, when the flow rates of the first mass flow meter 20 and the second mass flow meter 30 are compared, the extraction yield from which the raw material is extracted may be predicted. In addition, the extraction yield from which the raw material is extracted may be predicted through a change in the flow rate of the second mass flow meter 30 .

The second heat exchanger 500 may increase the temperature of the supercritical solvent in which the reaction is completed. The second heat exchanger 500 may heat the supercritical solvent so that the separation of the supercritical solvent and the extracted specific material more easily proceeds. The heated supercritical solvent may be transferred to the separator 600 .

The separator 600 may serve to separate gaseous carbon dioxide and a specific substance by depressurizing the supercritical solvent. For example, the separator 600 may include a plurality of separators, and each separator may separate a supercritical solvent and a specific substance under different pressure conditions.

The second condenser 700 may liquefy the supercritical solvent separated from the specific material. The liquefied solvent may be transferred to and stored in the storage tank 100 .

2 is a diagram for explaining a function of a controller according to an embodiment of the present invention.

1 and 2 , the controller 50 may directly control the high-pressure pump 200 and the valves V1 and V2 in the extraction and separation process of the supercritical device 1 . In particular, the controller 50 may control the flow of the supercritical solvent injected into the extractor 400 by controlling the first valve V1 .

The controller 50 may predict the extraction yield of the extractor 400 based on the flow rates of the supercritical solvent received from the first mass flow meter 20 and the second mass flow meter 30 . For example, the raw material charged into the extractor 400 may be dissolved in the supercritical solvent of carbon dioxide by the extraction process, and the first mass flow meter 20 measures the flow rate of the supercritical solvent introduced into the extractor 400 . and the second mass flow meter 30 may measure the flow rate of the supercritical solvent discharged from the extractor 400 . At this time, since the raw material is dissolved in the supercritical solvent discharged from the extractor 400 , the flow rate measured by the first mass flow meter 20 and the flow rate measured by the second mass flow meter 30 may be different from each other. Accordingly, the controller 50 may predict the amount of the sample dissolved in the supercritical solvent by the extraction process based on the flow rate of the supercritical solvent received from the first mass flow meter 20 and the second mass flow meter 30 . . In other words, the controller 50 determines that the extracted sample 400 is dissolved in the supercritical solvent based on the difference between the flow rate value received from the second mass flow meter 30 and the flow rate value received from the first mass flow meter 20 . amount can be determined.

When the controller 50 receives a signal indicating that the cover of the extractor 400 is opened by the sensor 450 , the controller 50 may stop the operation of the pump 200 . In addition, the controller 50 may close the first valve V1 disposed on the line in which the supercritical solvent is provided to the extractor 400 so that the supercritical solvent is not supplied to the extractor 400 .

For example, when the difference between the flow rate values at the front end and the rear end of the extractor 400 is smaller than a preset first set value, the controller 50 may stop the operation of the high pressure pump 200 . The first set value may be changed to a value preset by the user or may be changed by the user. If the difference between the flow rate value received from the second mass flow meter 30 and the flow rate value received from the first mass flow meter 20 is smaller than the first set value, it means that the amount of the sample dissolved by the supercritical solvent is very small. can mean that That is, the controller 50 may stop the operation of the high-pressure pump 200 by determining that it is no longer difficult to extract the sample from the raw material. At this time, the controller 50 may close the first valve V1 disposed on the line in which the supercritical solvent is provided to the extractor 400 . After stopping the operation of the high-pressure pump 200 , the controller 50 may notify the user that the sample loaded in the extractor 400 needs to be replaced. The user can accurately recognize the fact that the extraction process is completed by the signal output by the controller 50 (a signal that the sample needs to be replaced).

For example, when the difference between the flow rate values at the front end and the rear end of the extractor 400 is equal to or greater than the first set value and is smaller than the second set value, the controller 50 controls the difference between the flow rate value and the high pressure pump 200 to supply The flow rate of the high-pressure pump 200 may be reduced based on a table in which the relationship between the amounts of the supercritical solvent is stored in advance. The second setting value may be changed to a value preset by the user or may be changed by the user. The second set value may be greater than the first set value. When the yield at which the sample is extracted by the supercritical solvent is lowered, it may not be necessary to provide the supercritical solvent at the same flow rate or pressure as in the initial stage of the extraction process. That is, when the yield of sample extraction is lowered, even if the flow rate or pressure of the supercritical solvent supplied to the extractor 400 is reduced, the yield of sample extraction may not be affected. Accordingly, the controller 50 controls the high pressure pump based on the relationship between the difference between the flow rate values measured by the second mass flow meter 30 and the first mass flow meter 20 and the amount of the supercritical solvent supplied by the high pressure pump 200 . The flow rate of 200 can be controlled. Accordingly, excessive supply of the supercritical solvent may be prevented, thereby improving the economic feasibility of the extraction process.

After the user replaces the sample loaded in the extractor 400 , the controller 50 may control the high-pressure pump 200 to supply the supercritical solvent at a preset flow rate.

3 is a diagram illustrating a part of a supercritical device including a mass flow meter according to another embodiment of the present invention. FIG. 3 is a view for explaining that the extractor of the supercritical device of FIG. 1 is configured as a dual extractor.

Referring to FIG. 3 , the extractors 400a and 400b may include a first extractor 400a and a second extractor 400b. In the extractors 400a and 400b, a first inlet line 11 through which the supercritical solvent is injected into the first extractor 400a, a second inlet line 12 through which the supercritical solvent is injected into the second extractor 400b, a second The first discharge line 13 for transferring the mixture discharged from the first extractor 400a to the separator (600 in FIG. 1), and a second agent for transferring the mixture discharged from the second extractor 400b to the separator (600 in FIG. 1) 2 from the discharge line 14, the first recovery line 15 through which the supercritical solvent flows from the first extractor 400a to the second extractor 400b, and the second extractor 400b to the first extractor 400a. It may be provided to the second recovery line 16 into which the critical solvent is introduced. A first valve V1 is disposed on the first inlet line 11 , a second valve V2 is disposed on the second inlet line 12 , and a third valve V3 is disposed on the first outlet line 13 . is disposed on the second discharge line 14 , a fourth vab V4 is disposed on the first return line 15 , a fifth valve V5 is disposed on the first return line 15 , and a sixth valve V5 is disposed on the second return line 16 . A valve V6 may be arranged.

The first mass flow meter 20 may be disposed at the front end of the extractors 400a and 400b , and the second mass flow meter 30 may be disposed at the rear end of the extractors 400a and 400b . The first mass flow meter 20 may be disposed at the front end of the branching point of the first inlet line 11 and the second inlet line 12 . The second mass flow meter 20 may be disposed at the rear end of the branching point of the first discharge line 13 and the second discharge line 14 . Accordingly, the first mass flow meter 20 may measure the flow rate of the supercritical solvent supplied to the extractors 400a and 400b, and the second mass flow meter 30 may measure the supercritical solvent discharged from the extractors 400a and 400b. flow rate can be measured.

The controller 50 includes a first valve (V1), a second valve (V2), a third valve (V3), a fourth valve (V4), a fifth valve (V5), a sixth valve (V6) and a high-pressure pump ( 200) can be controlled. The controller 50 predicts the extraction yield of the first extractor 400a and the second extractor 400b during the extraction process to perform the extraction process through any of the first extractor 400a and the second extractor 400b. can decide whether After determining the extractor 400a or 400b to perform the extraction process, the controller 50 determines the first valve V1, the second valve V2, and the third to supply the supercritical solvent to the selected extractor 400a or 400b. The valve V3 , the fourth valve V4 , the fifth valve V5 , and the sixth valve V6 may be controlled. Specifically, the controller 50 controls the lines 11, 12, 13, 14, and 15 so that the supercritical solvent is provided to the extractor 400a or 400b of any one of the first extractor 400a and the second extractor 400b. , 16) on the valves V1, V2, V3, V4, V5, V6 can be controlled. During the extraction process, the extraction process may be performed only with one of the first extractor 400a and the second extractor 400b (400a or 400b).

For example, the controller 50 controls the first inflow when the difference between the flow rate values of the front end and the rear end of the first extractor 400a among the first extractor 400a and the second extractor 400b is smaller than a preset first set value. The supercritical solvent may be controlled to be supplied to the second extractor 400b by closing the first valve V1 on the line 11 and opening the second valve V2 on the second inlet line 12 . At this time, the controller 50 may close the third valve V3 , the fifth valve V5 , and the sixth valve V6 .

As an example, the controller 50 controls the second inflow when the difference between the flow rate values of the front end and the rear end of the second extractor 400b among the first extractor 400a and the second extractor 400b is smaller than a preset first set value. The supercritical solvent may be controlled to be supplied to the first extractor 400a by closing the second valve V2 on the line 12 and opening the first valve V1 on the first inlet line 11 . At this time, the controller 50 may close the fourth valve V4 , the fifth valve V5 , and the sixth valve V6 .

The controller 50 is supercritical supplied to the first inlet line 11 and the second inlet line 12 according to the difference in flow rate values of the front and rear ends of the first extractor 400a and the second extractor 400b, respectively. The flow rate of the solvent can be controlled.

For example, when the difference between the flow rate values of the front end and the rear end of the first extractor 400a among the first extractor 400a and the second extractor 400b is equal to or greater than a preset first set value and is smaller than the second set value, the controller Reference numeral 50 may reduce the flow rate of the high-pressure pump 200 in the process of supplying the supercritical solvent through the first inlet line 11 . The second setting value may be greater than the first setting value. When the difference between the flow rate values of the front end and the rear end of the first extractor 400a is equal to or greater than the first set value and is smaller than the second set value, the yield of extracting the sample charged into the first extractor 400a is lowered. can mean Accordingly, the controller 50 may reduce the flow rate of the high-pressure pump 200 to prevent wastage of the supercritical solvent. At this time, the controller 50 may close the third valve V3 , the fifth valve V5 , and the sixth valve V6 .

For example, when the difference between the flow rate values of the front end and the rear end of the second extractor 400b among the first extractor 400a and the second extractor 400b is equal to or greater than a preset first set value and is smaller than the second set value, the controller Reference numeral 50 may reduce the flow rate of the high-pressure pump 200 in the process of supplying the supercritical solvent through the second inlet line 12 . When the difference between the flow rate values of the front and rear ends of the second extractor 400b is equal to or greater than the first set value and is smaller than the second set value, the yield of extracting the sample charged into the second extractor 400b is lowered. can mean Accordingly, the controller 50 may reduce the flow rate of the high-pressure pump 200 to prevent wastage of the supercritical solvent. At this time, the controller 50 may close the fourth valve V4 , the fifth valve V5 , and the sixth valve V6 .

The raw material charged to the extractors 400a and 400b may be replaced by a batch type after stopping the operation of the supercritical device, and thus it may take time to replace the raw material. By using the dual extractors 400a and 400b according to the embodiment of the present invention, the extraction process is performed through the other extractor 400a or 400b while replacing the raw material charged in any one extractor 400a or 400b. can be Therefore, the process of extracting the raw material can be operated efficiently.

According to the embodiment of the present invention, even if the plurality of extractors (400a, 400b) are applied to the supercritical device, the second that is introduced into and discharged from the plurality of extractors (400a, 400b) through the two mass flowmeters (20, 30) The flow rate of the critical solvent can be measured.

4 is a diagram illustrating a part of a supercritical device including a mass flow meter according to another embodiment of the present invention. For brevity of description, descriptions of contents overlapping those of FIG. 3 will be omitted.

Referring to FIG. 3 , the mass flow meters 21 , 22 , and 30 may include a first mass flow meter 21 , a second mass flow meter 22 , and a third mass flow meter 30 . The first mass flow meter 21 may be disposed between the first point P1 where the first inlet line 11 and the second recovery line 16 meet and the first extractor 400a. The second mass flow meter 22 may be disposed between the second point P2 where the second inlet line 12 and the first return line 15 meet and the second extractor 400b. The third mass flow meter 30 may be disposed at a rear end of the third valve V3 on the first discharge line 13 and the fourth valve V4 on the second discharge line 14 .

The first mass flow meter 21 is a flow rate of the supercritical solvent supplied from the second recovery line 16 to the first extractor 400a and the second supplied to the first extractor 400a through the first inlet line 11 . The flow rate of the critical solvent can be measured. The second mass flow meter 22 includes a flow rate of the supercritical solvent supplied from the first recovery line 15 to the second extractor 400b and the second supplied to the second extractor 400b through the second inlet line 12 . The flow rate of the critical solvent can be measured. The third mass flow meter 30 may measure the flow rate of the supercritical solvent discharged from the first extractor 400a or the second extractor 400b.

For example, a sample may be injected into the second extractor 400b before the process of the first extractor 400a is completed. After the process of the first extractor 400a is completed, the supercritical solvent remaining in the first extractor 400a may be transferred to the second extractor 400b through the first recovery line 15 . After the supercritical solvent remaining in the first extractor 400a is transferred to the second extractor 400b through the first recovery line 15 , a new supercritical solvent may be transferred to the second extractor 400b. As the high-pressure supercritical solvent in the first extractor 400a flows into the second extractor 400b, the time the supercritical solvent is filled in the second extractor 400b may be shortened. That is, after the extraction process of the first extractor 400a, the high-pressure supercritical solvent remaining in the first extractor 400a is transferred to the second extractor 400b, and a new supercritical solvent is introduced through the second inlet line 12. The transfer time can be shortened.

For example, a sample may be injected into the first extractor 400a before the process of the second extractor 400b is completed. After the process of the second extractor 400b is completed, the supercritical solvent remaining in the second extractor 400b may be transferred to the first extractor 400a through the second recovery line 16 . After the supercritical solvent remaining in the second extractor 400b is transferred to the first extractor 400a through the second recovery line 16, a new supercritical solvent may be transferred to the first extractor 400a. As the high-pressure supercritical solvent in the second extractor 400b flows into the first extractor 400a, the time the supercritical solvent is filled in the first extractor 400a may be shortened. That is, after the extraction process of the second extractor 400b, the high-pressure supercritical solvent remaining in the second extractor 400b is transferred to the first extractor 400a, and a new supercritical solvent is introduced through the first inlet line 11. The transfer time can be shortened.

The controller 50 calculates the extraction yield of the first extractor 400a in consideration of the flow rate of the supercritical solvent supplied from the second recovery line 16 to the first extractor 400a measured by the first mass flow meter 21 . predictable. Specifically, the controller 50 controls the flow rate of the supercritical solvent recovered from the second extractor 400b measured by the first mass flow meter 30, the flow rate of the supercritical solvent supplied from the first inlet line 11, and the second The extraction yield of the first extractor 400a may be predicted by considering the flow rate of the supercritical solvent discharged through the first discharge line 13 .

The controller 50 calculates the extraction yield of the second extractor 400b in consideration of the flow rate of the supercritical solvent supplied from the first recovery line 15 to the second extractor 400b measured by the second mass flow meter 22 . predictable. Specifically, the controller 50 controls the flow rate of the supercritical solvent recovered from the first extractor 400a measured by the second mass flow meter 22, the flow rate of the supercritical solvent supplied from the second inlet line 12, and the second 2 The extraction yield of the second extractor 400b may be predicted in consideration of the flow rate of the supercritical solvent discharged through the discharge line 14 .

Above, embodiments of the present invention have been described with reference to the accompanying drawings, but those of ordinary skill in the art to which the present invention pertains can practice the present invention in other specific forms without changing the technical spirit or essential features. You will understand that there is Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

Claims (12)

a storage tank for storing carbon dioxide, which is a supercritical solvent;
an extractor connected to the storage tank to extract a specific substance as a sample and a supercritical solvent are supplied therein to react with each other;
a pump disposed between the storage tank and the extractor to supply a supercritical solvent from the storage tank to the extractor;
a separator for separating a specific substance and a supercritical solvent extracted through the extractor to discharge only a specific substance; and
A controller for controlling the flow rate of the pump based on information received from mass flow meters installed at the front and rear ends of the extractor,
A supercritical device comprising a mass flow meter. The method of claim 1,
The controller determines that the sample extracted from the extractor is dissolved in a supercritical solvent based on a difference in flow rate values received from each of the first mass flow meter disposed at the front end of the extractor and the second mass flow meter disposed at the rear end of the extractor. to judge the quantity,
A supercritical device comprising a mass flow meter. The method of claim 1,
When the difference between the flow rate value at the front end and the rear end of the extractor is smaller than a preset first set value, the controller stops the driving of the pump,
A supercritical device comprising a mass flow meter. 4. The method of claim 3,
The controller notifies the user that the sample loaded in the extractor needs to be replaced after stopping the operation of the pump,
A supercritical device comprising a mass flow meter. 4. The method of claim 3,
When the difference between the flow rate values at the front end and the rear end of the extractor is equal to or greater than the first set value and is smaller than the second set value, the controller determines the relationship between the difference between the flow rate value and the amount of supercritical solvent supplied by the pump. Reducing the flow rate of the pump based on a pre-stored table,
A supercritical device comprising a mass flow meter. The method of claim 1,
The extractor comprises a first extractor and a second extractor,
A first inlet line through which the supercritical solvent is injected into the first extractor, a second inlet line through which the supercritical solvent is injected into the second extractor, and a first discharge for transferring the mixture discharged from the first extractor to the multi-separator line, a second discharge line for transferring the mixture discharged from the second extractor to the multi-separator, a first recovery line through which a supercritical solvent flows from the first extractor to the second extractor, and the second extractor from the second extractor 1 is provided to the second recovery line into which the supercritical solvent is introduced into the extractor,
wherein the controller controls the valves on the lines to provide supercritical solvent to one of the first extractor and the second extractor;
A supercritical device comprising a mass flow meter. 7. The method of claim 6,
The controller closes the first valve on the first inlet line and closes the first valve of the first inlet line when the difference between the flow rate values of the front end and the rear end of the first extractor among the first extractor and the second extractor is smaller than a preset first set value. 2 Controlling the supercritical solvent to be supplied to the second extractor by opening the second valve on the inlet line,
A supercritical device comprising a mass flow meter. 7. The method of claim 6,
When the difference between the flow rate values of the front end and the rear end of the first extractor among the first extractor and the second extractor is equal to or greater than a preset first set value and is smaller than a second set value, the controller is configured to operate through the first inlet line. Reducing the flow rate of the pump in the process of supplying the supercritical solvent,
A supercritical device comprising a mass flow meter. 7. The method of claim 6,
The controller controls the flow rate of the supercritical solvent supplied to the first inlet line and the second inlet line according to the difference between the flow rate values of the front and rear ends of the first extractor and the second extractor, respectively,
A supercritical device comprising a mass flow meter. 7. The method of claim 6,
wherein the mass flow meters include a first mass flow meter, a second mass flow meter and a third mass flow meter;
the first mass flow meter is disposed between a point where the first inlet line and the second return line meet and the first extractor;
the second mass flow meter is disposed between a point where the second inlet line and the first return line meet and the second extractor;
wherein the third mass flow meter is disposed at a rear end of the first extractor and the second extractor,
A supercritical device comprising a mass flow meter. 11. The method of claim 10,
The first mass flow meter measures the flow rate of the supercritical solvent supplied to the first extractor from the second recovery line and the flow rate of the supercritical solvent supplied to the first extractor through the first inlet line,
The second mass flow meter measures the flow rate of the supercritical solvent supplied to the second extractor from the first recovery line and the flow rate of the supercritical solvent supplied to the second extractor through the second inlet line,
A supercritical device comprising a mass flow meter. The method of claim 1,
The extractor includes a cover that is opened for sample replacement and a sensor for detecting whether the cover is opened,
When the cover is opened by the sensor, the controller stops the operation of the pump and closes a valve disposed on a line through which the supercritical solvent is provided to the extractor,
A supercritical device comprising a mass flow meter.

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