KR101075326B1 - Extraction system using continuous recycling of liquid CO2 - Google Patents

Abstract

The present invention provides a storage tank for storing carbon dioxide in a liquid state, an extraction tank in which an extraction reaction takes place, a separator for separating an object and liquid carbon dioxide, and a control device composed of a level sensor, a controller, and a liquid flow valve to continuously recycle the liquid carbon dioxide. It is configured to include. Among the regulators, the level sensor measures the liquid level of liquid carbon dioxide in the extraction tank and transmits the measured value to the controller. The liquid flow valve discharges the liquid carbon dioxide in the extraction tank to the separation tank based on the liquid level measurement value of the liquid carbon dioxide sent to the controller. According to the present invention, the liquid carbon dioxide in the extraction tank through the control device to maintain a constant liquid level to provide a system that can continuously recycle the liquid carbon dioxide.

Description

Extraction system using continuous recycling of liquid CO2

1 shows a schematic configuration of a plasticizer extraction device for forming a microporous membrane of a conventional secondary battery.

Figure 2 shows the configuration of the extraction system using the continuous recycling of liquefied carbon dioxide according to an embodiment of the present invention.

The present invention relates to an extraction system using continuous recycling of liquid carbon dioxide. More specifically, the process of storing, extracting, and separating liquid carbon dioxide is continuously performed in a plasticizer extraction apparatus for forming a microporous membrane in a secondary battery. A recycling system is recycled.

As an extraction system using carbon dioxide, an extraction system using supercritical carbon dioxide has been studied. However, since supercritical carbon dioxide is formed in a very high pressure region, it is difficult to manufacture a high pressure vessel and secure safety. Therefore, research on the extraction system using liquid carbon dioxide formed at a relatively low pressure and excellent extraction ability has been conducted along with the extraction system using supercritical carbon dioxide.

Hereinafter, an extraction system using carbon dioxide according to the prior art will be described with reference to FIG. 1. 1 is a schematic configuration diagram showing an extraction system using carbon dioxide according to the prior art.

The extraction system using the recirculation of liquid carbon dioxide according to the prior art is composed of a reservoir (10), an extraction tank (13) and a separation tank (16).

Here, the storage tank 10 stores the carbon dioxide in a liquid state and stores the gaseous carbon dioxide recovered from the separation tank 16 in a liquid state during recycling. In the extraction tank 13, a reaction between the material containing the extraction target material and the liquid carbon dioxide introduced from the storage tank 10 is performed. The separation tank 16 separates the liquid carbon dioxide including the extract introduced from the extraction tank 13 from the extract.

That is, the storage tank 10 stores the carbon dioxide in a liquid state, and condenses the gas carbon dioxide introduced from the separation tank 16 to make it into a liquid state and stores it. The storage tank 10 is provided with a first heat exchanger 11 for condensation of gaseous carbon dioxide. The material containing the extraction target material and the liquid carbon dioxide introduced from the storage tank 10 react in the extraction tank 13. Inflow of liquid carbon dioxide from the reservoir 10 into the extraction tank 13 is caused by a pressure difference. When the pressure of the storage tank 10 and the extraction tank 13 becomes the same, the liquid carbon dioxide in the storage tank 10 flows into the extraction tank 13 by the high pressure liquid pump 12. In the extraction tank 13, a second heat exchanger 14 is provided for maintaining the liquid carbon dioxide in a state necessary for extraction. The liquid carbon dioxide containing the extracted object of reaction in the extraction tank 13 flows into the separation tank 16. A third heat exchanger 17 is installed in the separation tank 16 to separate the extraction target material and the liquid carbon dioxide. The third heat exchanger 17 vaporizes liquid carbon dioxide.

Each step in the reservoir 10, the extraction tank 13 and the separation tank 16 is not a continuous process, but consists of a discontinuous process in which the process of the next step is performed after the completion of one step. Therefore, a large amount of liquid carbon dioxide should be used because the liquid carbon dioxide required for the reaction must be introduced into the extraction tank 13 at a time. Since the amount of carbon dioxide required for the reaction is large, the volume of the storage tank 10 storing carbon dioxide increases, thereby increasing the investment cost. Recirculation takes place step by step, resulting in longer extraction times.

The technical problem to be achieved by the present invention is to reduce the amount of carbon dioxide required to extract the extract.

In addition, another technical problem to be achieved by the present invention is to reduce the investment cost for the extraction facility by reducing the amount of carbon dioxide used, and to reduce the time required for the process by performing a continuous extraction process.

Extraction system using a continuous recycling of liquid carbon dioxide for achieving the above technical problem, an extraction tank for storing the liquid carbon dioxide and the extraction tank and the liquid carbon dioxide introduced from the reservoir reacts to produce an extract and liquid carbon dioxide, extraction A separation tank for separating the liquid carbon dioxide and the extract introduced from the tank, and outputting the separated liquid carbon dioxide to the storage tank, and a control device for adjusting the amount of liquid carbon dioxide in the extraction tank so that the liquid carbon dioxide in the extraction tank is maintained by a predetermined amount. do.

The control device is preferably configured to serve to continuously circulate liquid carbon dioxide into the reservoir, extraction tank and separation tank.

In the present invention, the control politics is a level sensor for measuring the amount of liquid carbon dioxide in the extraction tank, a controller for adjusting the flow control valve in response to the measured value of the liquid carbon dioxide measured by the level sensor, and the liquid measured by the controller It is preferable to include a liquid flow valve for controlling the amount of liquid carbon dioxide in the extraction tank based on the amount of carbon dioxide.

In the present invention, the storage tank preferably further includes a first heat exchanger for liquefying gaseous carbon dioxide introduced from the separation tank.

In the present invention, it is preferable that the extraction tank further includes a second heat exchanger for maintaining a predetermined reaction temperature so that the reaction of the liquid carbon dioxide introduced from the storage tank and the extraction target is actively performed.

In the present invention, the separation tank preferably further includes a third heat exchanger for supplying energy so that the separation reaction of the liquid carbon dioxide and the extract introduced from the extraction tank can be made.                     

The present invention preferably further comprises a high pressure liquid pump for supplying liquid carbon dioxide from the reservoir to the extraction tank.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. These examples are only for illustrating the present invention, and the protection scope of the present invention is not limited by these examples.

 Hereinafter, an embodiment of the present invention will be described with reference to FIG. 2.

2 is a schematic diagram illustrating an extraction system using continuous recycling of liquid carbon dioxide according to an embodiment of the present invention.

2, the extraction system of the present invention comprises a reservoir 20, an extraction tank 23 and a separation tank 28. Here, the storage tank 20 stores liquid carbon dioxide and stores the gaseous carbon dioxide recovered from the separation tank 28 in a liquid state during recycling. The extraction tank 23 is a reaction between the material containing the extraction target material and the liquid carbon dioxide introduced from the storage tank 20. Separation tank 28 separates the liquid carbon dioxide containing the extract introduced from the extraction tank 23 and the extract.

Liquid carbon dioxide in the reservoir 20 is transferred by the pressure difference between the reservoir 20 and the extraction tank 23. When the pressure of the reservoir 20 and the extraction tank 23 becomes the same, the liquid carbon dioxide in the reservoir 20 flows into the extraction tank 23 by the high pressure liquid pump 22. It is preferable to install a second heat exchanger 24 in the extraction tank 23 so that the reaction of the material containing the extraction target material and the liquid carbon dioxide introduced from the storage tank 20 can be actively performed. The second heat exchanger 24 controls the reaction temperature of the liquid carbon dioxide in the extraction tank. It is preferable to provide a temperature sensor in the extraction tank 23. The temperature sensor controls the heat exchange amount of the second heat exchanger 24, and allows the second heat exchanger 24 to adjust the temperature required for the reaction of the liquid carbon dioxide.

The level sensor 25 inside the extraction tank 23 senses the amount of liquid carbon dioxide inside the extraction tank 23. The measured value of the liquid carbon dioxide detected by the level sensor 41 is transmitted to the controller 42. The controller 42 adjusts the liquid flow rate valve 43 based on the amount of liquid carbon dioxide transmitted from the level sensor 41. The liquid flow valve 43 discharges the liquid carbon dioxide in the extraction tank to the separation tank 28 based on the amount of liquid carbon dioxide sent to the controller 42. The liquid flow valve 27 flows the liquid carbon dioxide in the extraction tank 23 to the separation tank 28 to maintain the liquid level of the liquid carbon dioxide in the extraction tank 23.

When the amount of liquid carbon dioxide in the extraction tank 23 is adjusted through the adjusting device 40 including the level sensor 41, the controller 42, and the liquid flow valve 43, the liquid carbon dioxide required for the reaction is extracted from the beginning. It is not necessary to inject into the tank 23 at once. The adjusting device adjusts the liquid level of the liquid carbon dioxide so that the material including the extraction target material in the extraction tank 23 can be submerged by the liquid carbon dioxide. When liquid carbon dioxide flows into the extraction tank 23 during the reaction time, the liquid carbon dioxide containing the extraction target material of which the reaction is terminated is discharged to the separation tank 28. The flow of liquid carbon dioxide necessary for extraction improves the contact between the liquid carbon dioxide in the extraction tank 23 and the extraction target material. It is preferable that recycling takes place while maintaining the liquid level of liquid carbon dioxide in the extraction tank 23. If the amount of liquid carbon dioxide in the extraction tank 23 is large, the volume of the liquid carbon dioxide supplied becomes larger than the volume of the extraction tank 23, and the pressure rises. When the pressure in the extraction tank 23 rises, the state of the liquid carbon dioxide may be broken.

The liquid carbon dioxide including the extraction object of which the reaction is completed, flows out from the extraction tank 23 to the separation tank 28. The liquid carbon dioxide containing the extracted object introduced into the separation tank 28 is introduced into the separation tank 28 and is rapidly expanded. The liquid carbon dioxide including the extraction object rapidly expanded in the separation tank 28 is vaporized and separated from the extraction object. Separation tank 28 may be provided with a third heat exchanger for heat supply. The third heat exchanger 28 supplies heat to the separation tank 28 to separate the extract object and the liquid carbon dioxide.

The gaseous carbon dioxide separated from the extraction object in the separation tank 28 is recovered to the storage tank 20 by the gas booster 30. A first heat exchanger 21 for liquefying the gaseous carbon dioxide separated in the separation tank 28 may be provided. The first heat exchanger 21 is preferably installed in the reservoir 20. The first heat exchanger 21 liquefies gaseous carbon dioxide introduced into the reservoir 20 and adjusts the temperature in the reservoir 20 so that the carbon dioxide in the reservoir 20 can be maintained in a liquid state.

As described above, the present invention improves the use efficiency of liquid carbon dioxide to reduce the amount of carbon dioxide required for the reaction. The reduction in the amount of carbon dioxide used has the effect of reducing the volume of the reservoirs storing carbon dioxide and the extraction tanks in which the reaction takes place.

Therefore, the investment cost according to the high pressure container of the storage tank and the extraction tank is reduced. The flow of carbon dioxide continuously in the extraction tank improves the extraction power and shortens the time required for the extraction process.

Claims (7)

A reservoir for storing liquid carbon dioxide; An extraction tank for producing an extract and liquid carbon dioxide by reacting an extract object with liquid carbon dioxide introduced from the storage tank; A separation tank separating the liquid carbon dioxide and the extract introduced from the extraction tank, and distilling the separated liquid carbon dioxide into the storage tank; And And an adjusting device for controlling the amount of liquid carbon dioxide in the extraction tank so that the object to be extracted in the extraction tank is completely submerged by the liquid carbon dioxide. Further comprising a gas booster for recovering the gas carbon dioxide separated from the extract by the separation tank to the storage tank, The reservoir further includes a first heat exchanger for liquefying gaseous carbon dioxide recovered through the gas booster, The extraction tank further includes a second heat exchanger for adjusting a temperature required for reaction of the liquid carbon dioxide introduced from the storage tank and the extract object, and a temperature sensor for controlling the heat exchange amount of the second heat exchanger. Extraction system using continuous recycling of The method of claim 1, Wherein said control device continuously circulates said liquid carbon dioxide to said storage, extraction and separation tanks. The method of claim 2, The control device, the level sensor for measuring the amount of liquid carbon dioxide in the extraction tank; A controller receiving a measurement value of the liquid carbon dioxide measured by the level sensor; And And a liquid flow valve for controlling the amount of liquid carbon dioxide in the extraction tank based on the amount of liquid carbon dioxide measured under the control of the controller. delete The method of claim 3, The extraction tank further includes a second heat exchanger for maintaining a reaction temperature at which the reaction of the liquid carbon dioxide introduced from the reservoir and the extraction object is carried out. The method of claim 3, The separation tank further comprises a third heat exchanger for supplying energy to the separation reaction of the liquid carbon dioxide and the extract introduced from the extraction tank using a continuous recycling of liquid carbon dioxide. The method of claim 3, And a high pressure liquid pump for supplying liquid carbon dioxide from the reservoir to the extraction tank.

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