KR20230118421A - Adsorption and desorption VOC recovery equipment and recovery method - Google Patents

Abstract

The absorption and desorption type VOC recovery facility according to the present invention includes a gas inlet for introducing VOC gas containing VOC and a knockout drum (KO drum) in which condensed liquid generated while the VOC gas is moved through a pipe is separated, and A blower for moving the VOC gas from which the condensed liquid is separated from the knockout drum, a plurality of adsorption towers for adsorbing VOC of the VOC gas, and a gas outlet connected to the adsorption tower to discharge the VOC-removed gas to the outside; An air injection unit connected to the adsorption tower to inject air into the adsorption tower, a vacuum pump to move the VOC adsorbed to the adsorption tower, and a C-VRU (Cryogenic-Vapor Recovery Unit) in which the VOC is cooled, condensed, and recovered, and a refrigerant A binary refrigerator for rapidly cooling the C-VRU, a VOC storage unit for storing the VOC condensed and recovered in the C-VRU, and a plurality of valves for controlling the flow rate of the fluid moving through the pipe, the components of the fluid, pressure, It is characterized in that it is configured to include a plurality of sensors for sensing concentration, flow rate, and temperature.

Description

Adsorption and desorption VOC recovery equipment and recovery method {Adsorption and desorption VOC recovery equipment and recovery method}

The present invention relates to an adsorption-and-desorption type VOC recovery facility and recovery method, and more particularly, after adsorbing VOC (Volatile Organic Compounds) to activated carbon installed inside an adsorption tower, the VOC adsorbed to the activated carbon is adsorbed with a vacuum pump An adsorption/desorption type VOC recovery facility and method for recovering the VOC in liquid form by desorbing it from the activated carbon using an air valve and then rapidly cooling and condensing it in the C-VRU.

In general, VOCs (Volatile Organic Compounds), which are generated in large quantities at various industrial sites such as painting factories, petrochemical factories, rubber manufacturing factories, and sewage / excreta treatment plants, have been a cause of environmental pollution.

Conventional methods for removing VOCs generated in industrial sites can be largely divided into combustion methods and adsorption methods.

The double adsorption method uses activated carbon to remove VOCs by being adsorbed on the activated carbon. When adsorption is performed for a long period of time, the activated carbon in the adsorption tower is saturated and the efficiency is reduced, and the activated carbon must be frequently replaced.

KR 10-2021-0145039 A 2021.12.01 KR 10-1912752 B1 2018.10.23 KR 10-1512648 B1 2015.04.10

The present invention was made to solve the above problems,

An object of the present invention is to adsorb VOC (Volatile Organic Compounds) to activated carbon installed inside the adsorption tower, and then use a vacuum pump and an air valve to adsorb the VOC adsorbed to the activated carbon before the activated carbon is saturated and the efficiency decreases. It is to provide an adsorption-and-desorption type VOC recovery facility and recovery method for recovering the VOC in a liquid form by desorbing it from the activated carbon and then rapidly cooling and condensing it in the C-VRU.

In order to solve the above technical problems,

The absorption and desorption type VOC recovery facility according to the present invention includes a gas inlet for introducing VOC gas containing VOC and a knockout drum (KO drum) in which condensed liquid generated while the VOC gas is moved through a pipe is separated, and A blower for moving the VOC gas from which the condensed liquid is separated from the knockout drum, a plurality of adsorption towers for adsorbing VOC of the VOC gas, and a gas outlet connected to the adsorption tower to discharge the VOC-removed gas to the outside; An air injection unit connected to the adsorption tower to inject air into the adsorption tower, a vacuum pump to move the VOC adsorbed to the adsorption tower, and a C-VRU (Cryogenic-Vapor Recovery Unit) in which the VOC is cooled, condensed, and recovered, and a refrigerant A binary refrigerator for rapidly cooling the C-VRU, a VOC storage unit for storing the VOC condensed and recovered in the C-VRU, and a plurality of valves for controlling the flow rate of the fluid moving through the pipe, the components of the fluid, pressure, It is characterized in that it is configured to include a plurality of sensors for sensing concentration, flow rate, and temperature.

Also preferably, the blower increases the rotational speed of the blower when the pressure inside the knockout drum sensed by the sensor installed on one side of the knockout drum by the blower controller installed on one side of the blower exceeds 10mmH ₂ O And, when it is less than 10mmH ₂ O, the rotational speed of the blower is reduced to automatically maintain the pressure inside the knockout drum at 10mmH ₂ O, and automatically adjust the flow rate of the VOC gas transferred to the adsorption tower. do.

Also preferably, the adsorption tower is installed on one side of the adsorption tower and when the valve connected to the blower is opened, the VOC is adsorbed to the activated carbon installed inside the adsorption tower and at the same time installed on one side of the adsorption tower and connected to the gas outlet. It is characterized in that the valve is opened and the gas from which the VOC is removed is discharged to the outside.

Also preferably, in the adsorption tower, when the valve installed on one side of the adsorption tower is closed, the valve installed on one side of the adsorption tower and connected to the air injection unit is opened, and air from the outside is moved into the adsorption tower, and at the same time, the vacuum pump is operated and the valve installed on one side of the adsorption tower and connected to the vacuum pump is opened, and the VOC adsorbed on the activated carbon installed inside the adsorption tower is converted into gaseous recovery gas and moved to the C-VRU. do.

Also preferably, the C-VRU includes a plurality of condensing units for condensing the VOC included in the recovered gas transferred from the adsorption tower, and the sensor installed on one side of the condensing unit measures the temperature of the condensation unit. And according to the measured temperature, the valve installed in the pipe connected from the binary refrigerator to the condenser is opened and closed, and the refrigerant cooled to -80 ° C or less in the binary refrigerator is moved to the condenser, and the condenser is transferred to the binary refrigerator. The sensor installed in the pipe connected to the condenser measures the pressure inside the condenser, and according to the measured pressure, the valve installed in the pipe connected from the condenser to the binary refrigerator is opened and closed so that the refrigerant passing through the condenser is The recovered gas, which is transferred to the binary refrigerator and includes the VOC transferred from the adsorption tower, is moved to the condensing unit, and the recovered gas is cooled and condensed by the refrigerant to be divided into the VOC and the remaining recovered gas, and the condensing unit The VOC condensed in is moved to the VOC storage unit by the valve, and the recovered gas remaining in the condensation unit after being condensed in the condensation unit is moved to the adsorption tower again.

Also preferably, the VOC storage unit is characterized in that the VOC is recovered in the form of a liquid.

On the other hand, the adsorption and desorption type VOC recovery method includes a first step in which VOC gas containing VOC is introduced into the gas inlet and a second step in which the condensed liquid generated while the VOC gas is moved through a pipe is separated from the knockout drum and the rust A third step of sensing the pressure inside the outer drum and a fourth step of operating a blower according to the pressure inside the knockout drum sensed in the third step, and the condensed liquid is separated from the knockout drum by the blower. Some of the plurality of adsorption towers connected in parallel with the fifth step of moving the VOC gas to the adsorption tower are installed on one side of the adsorption tower, and a valve connected to the blower is opened, and the VOC gas containing the VOC moves to the adsorption tower. As the VOC is adsorbed on the activated carbon installed inside the adsorption tower, the valve installed on one side of the adsorption tower and connected to the gas outlet is opened, and the gas from which the VOC is removed is discharged to the outside, and the VOC gas containing the VOC is discharged to the outside. The adsorption tower that does not move to the adsorption tower is installed on one side of the adsorption tower and the valve connected to the air injection part is opened, and air is moved from the outside into the adsorption tower, and at the same time the vacuum pump is operated and installed on one side of the adsorption tower to be connected to the vacuum pump A sixth step in which the valve is opened and the VOC adsorbed on the activated carbon installed inside the adsorption tower is converted into gaseous recovered gas and transferred to C-VRU; It is characterized by a seventh step of cooling and condensing in the VRU and an eighth step of storing the VOCs cooled and condensed in the seventh step in a VOC storage unit.

According to the adsorption/desorption type VOC recovery facility and recovery method of the present invention made as described above, the following effects can be obtained.

The present invention relates to an adsorption-and-desorption type VOC recovery facility and recovery method, and more particularly, after adsorbing VOC (Volatile Organic Compounds) to activated carbon installed inside an adsorption tower, the VOC adsorbed to the activated carbon is adsorbed with a vacuum pump An adsorption/desorption type VOC recovery facility and recovery method in which the VOC is recovered in liquid form by rapid cooling and condensation in a C-VRU after recovering from the activated carbon using an air valve.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

1 is a block diagram showing an adsorption-and-detachable VOC recovery facility according to a preferred embodiment of the present invention.
Figure 2 is a detailed configuration diagram showing a desorption type VOC recovery facility according to a preferred embodiment of the present invention.
Figure 3 is a flow chart showing the operation of the blower of the desorption type VOC recovery equipment according to a preferred embodiment of the present invention.
4 is a block diagram showing an adsorption tower of an adsorption/desorption type VOC recovery facility according to a preferred embodiment of the present invention.
Figure 5 is a flow chart showing the operation of the adsorption tower of the adsorption and desorption type VOC recovery facility according to a preferred embodiment of the present invention.
6 is a configuration diagram showing a V-CRU of a desorption-type VOC recovery facility according to a preferred embodiment of the present invention.
Figure 7 is a flow chart showing a desorption type VOC recovery method according to a preferred embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings in order to describe in detail enough for those skilled in the art to easily implement the technical idea of the present invention.

1 is a configuration diagram showing a desorption type VOC recovery facility according to a preferred embodiment of the present invention, and FIG. 2 is a detailed configuration diagram showing a desorption type VOC recovery facility according to a preferred embodiment of the present invention.

Referring to FIGS. 1 and 2, the adsorption and desorption type VOC (Volatile Organic Compound) recovery facility includes a gas inlet 100, a knockout drum (KO drum) 200, a blower 300, A plurality of adsorption towers 400, a gas outlet 420, an air injection unit 430, a vacuum pump 500, a cryogenic-vapor recovery unit (C-VRU) 600, a binary refrigerator 700, a VOC storage unit ( 800), a plurality of valves 900, and a plurality of sensors 1000.

Here, VOC gas containing VOC is introduced into the gas inlet 100 and the VOC gas introduced into the gas inlet 100 may be moved to the knockout drum 200 through a pipe.

At this time, the condensed liquid is generated while the VOC gas moves through the pipe, and the generated condensed liquid can be separated from the knockout drum 200.

And, the VOC gas from which the condensed liquid is removed may be moved to the adsorption tower 400 by the blower 300.

Figure 3 is a flow chart showing the operation of the blower of the absorption and desorption type VOC recovery equipment according to a preferred embodiment of the present invention.

Referring to FIG. 3 , the blower 300 is sensed by the blower controller 310 installed on one side of the blower 300 and the sensor 1000_1 installed on one side of the knockout drum 200. (200) When the internal pressure is greater than 10mmH ₂ O, the rotational speed of the blower 300 increases, and when the pressure is less than 10mmH ₂ O, the rotational speed of the blower 300 is decreased to increase the internal pressure of the knockout drum 200. The pressure can be automatically maintained at 10 mmH ₂ O.

At this time, the blower controller 310 may include a self-learning unit and generate a deep learning solution based on the self-learning data and domain ontology provided from the outside of the stored data.

Here, the blower controller 310 may adjust the rotational speed of the blower 300 using the generated deep learning solution and the internal pressure of the knockout drum 200 sensed by the sensor 1000_1. .

And, when generating the deep learning solution, the lowest value of the loss function is found using an Adam (Adaptive Moment Estimation, Adam) optimizer.

In addition, the Adam optimizer, which is currently the most widely used deep learning optimization technique, stores the exponential mean of the slopes calculated by the Momentum method and the exponential mean of the square values of the slopes of RMSProp.

는 계산하는 기울기의 지수평균,

는 계산하는 기울기의 제곱값의 지수평균이다.here,

is the exponential mean of the slope to be calculated,

is the exponential mean of the squared values of the slopes to be calculated.

와

는

과

가 0으로 초기화 되어 있기 때문에 학습의 초반부에서는

와

가 0에 가깝게 bias 되었을 것이라고 판단하여 이를 unbiased하게 만들어준 보정값이다.here,

and

Is

class

Since is initialized to 0, at the beginning of learning

and

This is the correction value that made it unbiased by judging that is likely to have been biased close to 0.

은 0.9,

는 0.999,

은 10^-8을 사용한다.here,

is 0.9;

is 0.999,

uses 10 ^-8 .

4 is a block diagram showing the adsorption tower of the adsorption/desorption type VOC recovery facility according to a preferred embodiment of the present invention, and FIG. 5 shows the operation of the adsorption tower of the adsorption/desorption type VOC recovery facility according to a preferred embodiment of the present invention. It is a flow chart.

4 to 5, the adsorption tower 400 is installed on one side of the adsorption tower 400, and some of the plurality of adsorption towers 400 connected in parallel are connected to the blower 300. The valve 900_1 is opened, the VOC gas containing the VOC is moved to the adsorption tower 400, and the VOC is adsorbed to the activated carbon 410 installed inside the adsorption tower 400, and at the same time installed on one side of the adsorption tower 400, the gas The valve 900_2 connected to the outlet 420 is opened, and the gas from which the VOC is removed is discharged to the outside, and the adsorption tower 400 in which the VOC gas containing the VOC is not moved to the inside is the adsorption tower 400 The valve 900_3 installed on one side and connected to the air injection unit 430 is opened, and air is moved from the outside into the adsorption tower 400, and at the same time, the vacuum pump 500 is operated and one side of the adsorption tower 400 The valve 900_4 installed in and connected to the vacuum pump 500 is opened, and the VOC adsorbed on the activated carbon 410 installed inside the adsorption tower 400 is converted into gaseous recovery gas, and the C-VRU ( 600).

6 is a configuration diagram showing a V-CRU of a desorption-type VOC recovery facility according to a preferred embodiment of the present invention.

Referring to FIG. 6, the C-VRU 600 is configured to include a plurality of condensing units 610 for condensing the VOC included in the recovered gas transferred from the adsorption tower 400, and the condensing units ( The valve ( 900_5) is opened and closed so that the refrigerant cooled to -80° C. or lower in the binary refrigerator 700 is moved to the condensing unit 610, and the condensing unit 610 is connected to a pipe connected to the binary refrigerator 700. The installed sensor 1000_3 measures the pressure inside the condensing unit 610, and according to the measured pressure, the valve 900_6 installed in the pipe connected from the condensing unit 610 to the binary refrigerator 700 opens. Closed, the refrigerant passing through the condensing unit 610 is moved to the binary refrigerator 700, and the recovered gas containing the VOC transferred from the adsorption tower 400 is moved to the condensing unit 610, The recovered gas is cooled and condensed by the refrigerant to be divided into the VOC and residual recovered gas, and the VOC condensed in the condenser 610 is moved to the VOC storage unit 800 by the valve 900_7. , After condensation in the condensing unit 610, the recovered gas remaining in the condensing unit 610 may be moved to the adsorption tower 400 again.

Here, the VOC storage unit 800 can recover the VOC in the form of a liquid.

Figure 7 is a flow chart showing a desorption type VOC recovery method according to a preferred embodiment of the present invention.

Referring to FIG. 7, the adsorption and desorption type VOC recovery method includes a first step (S100) in which VOC gas containing VOC is introduced into the gas inlet 100 and the condensed liquid generated while the VOC gas is moved through the pipe is melted. The second step of separating from the outer drum 200 (S200), the third step of sensing the pressure inside the knockout drum 200 (S300), and the knockout drum sensed in the third step (S300) ( 200) A fourth step (S400) of operating the blower 300 according to the internal pressure, and the VOC gas separated from the condensed liquid in the knock-out drum 200 by the blower 300 is absorbed into the adsorption tower 400 Some of the plurality of adsorption towers 400 connected in parallel with the fifth step (S500) are installed on one side of the adsorption tower 400 and the valve 900_1 connected to the blower 300 is opened to contain the VOC. The VOC gas is moved to the adsorption tower 400, and the VOC is adsorbed on the activated carbon 410 installed inside the adsorption tower 400, and at the same time, a valve installed on one side of the adsorption tower 400 and connected to the gas outlet 420 (900_2) is opened, the gas from which the VOC is removed is discharged to the outside, and the adsorption tower 400, in which the VOC gas containing the VOC is not moved to the inside, is installed on one side of the adsorption tower 400 and is an air injection unit. The valve 900_3 connected to 430 is opened, and air is moved from the outside into the adsorption tower 400, and at the same time, the vacuum pump 500 is operated and installed on one side of the adsorption tower 400, and the vacuum pump 500 A sixth step (S600) in which the connected valve 900_4 is opened and the VOC adsorbed on the activated carbon 410 installed inside the adsorption tower 400 is converted into gaseous recovered gas and moved to the C-VRU 600; A seventh step (S700) in which the VOC of the recovery gas recovered in the sixth step (S600) is cooled and condensed in the C-VRU (600) and the VOC cooled and condensed in the seventh step (S700) is stored as VOC. It may be the eighth step (S800) stored in the unit 630.

100: gas inlet 200: knockout drum
300: blower 310: blower controller
400: adsorption tower 410: activated carbon
420: gas outlet 430: air inlet
500: vacuum pump 600: C-VRU
610: condensation unit 700: binary refrigerator
800: VOC storage unit 900: valve
1000: sensor

Claims (7)

A gas inlet 100 for introducing VOC gas containing VOC;
A knock-out drum 200 in which condensed liquid generated while the VOC gas is moved through the pipe is separated;
a blower 300 for moving the VOC gas from which the condensed liquid is separated from the knock-out drum 200;
A plurality of adsorption towers (400) in which the VOC of the VOC gas is adsorbed;
a gas outlet 420 connected to the adsorption tower 400 and through which the VOC-removed gas is discharged to the outside;
an air injection unit 430 connected to the adsorption tower 400 and injecting air into the adsorption tower 400;
a vacuum pump 500 for moving the VOC adsorbed in the adsorption tower 400;
a C-VRU (600) in which the VOC is cooled, condensed, and recovered;
A binary refrigerator 700 for rapidly cooling the C-VRU 600 using a refrigerant;
a VOC storage unit 800 in which the VOC condensed and recovered in the C-VRU 600 is stored;
A plurality of valves 900 for controlling the flow rate of the fluid moving through the pipe; and
It is configured to include a plurality of sensors 1000 for sensing the composition, pressure, concentration, flow rate, and temperature of the fluid.
Characterized by adsorption and desorption type VOC recovery equipment.
According to claim 1,
The blower 300 is
The pressure inside the knock-out drum 200 sensed by the sensor 1000_1 installed on one side of the knock-out drum 200 by the blower controller 310 installed on one side of the blower 300 is greater than 10 mmH ₂ O In this case, the rotation speed of the blower 300 increases, and when it is less than 10 mmH ₂ O, the rotation speed of the blower 300 decreases to automatically maintain the pressure inside the knockout drum 200 at 10 mmH ₂ O, Automatically adjusting the flow rate of the VOC gas transferred to the adsorption tower (400)
Characterized by adsorption and desorption type VOC recovery equipment.
According to claim 2,
The adsorption tower 400 is
When the valve 900_1 installed on one side of the adsorption tower 400 and connected to the blower 300 is opened, the VOC is adsorbed to the activated carbon 410 installed inside the adsorption tower 400, and at the same time the adsorption tower 400 The valve 900_2 installed on one side and connected to the gas outlet 420 is opened so that the VOC-removed gas is discharged to the outside.
Characterized by adsorption and desorption type VOC recovery equipment.
According to claim 3,
The adsorption tower 400 is
When the valve 900_1 installed on one side of the adsorption tower 400 is closed, the valve 900_3 installed on one side of the adsorption tower 400 and connected to the air injection unit 430 is opened to supply air from the outside. The valve 900_4 installed on one side of the adsorption tower 400 and connected to the vacuum pump 500 is opened and moved into the adsorption tower 400, and the vacuum pump 500 is operated at the same time. The VOC adsorbed on the activated carbon 410 is converted into gaseous recovery gas and transferred to the C-VRU 600.
Characterized by adsorption and desorption type VOC recovery equipment.
According to claim 1,
The C-VRU 600 is
It is configured to include a plurality of condensing units 610 for condensing the VOC included in the recovered gas transferred from the adsorption tower 400, and the sensor 1000_2 installed on one side of the condensing unit 610 is The temperature of the side part 610 is measured and according to the measured temperature, the valve 900_5 installed in the pipe connected from the binary refrigerator 700 to the condensing unit 610 is opened and closed to -80 in the binary refrigerator 700. The refrigerant cooled below °C is moved to the condensing unit 610, and the sensor 1000_3 installed in a pipe connected from the condensing unit 610 to the binary refrigerator 700 is inside the condensing unit 610. The pressure is measured and the valve 900_6 installed in the pipe connected from the condenser 610 to the binary refrigerator 700 is opened and closed according to the measured pressure, so that the refrigerant passing through the condenser 610 The recovered gas, which is moved to the binary refrigerator 700 and includes the VOCs transferred from the adsorption tower 400, is moved to the condenser 610, and the recovered gas is cooled and condensed by the refrigerant to obtain the VOC and Divided into the remaining recovery gas, the VOC condensed in the condensing unit 610 is moved to the VOC storage unit 800 by the valve 900_7, and after being condensed in the condensing unit 610, the condensing unit ( 610) The recovery gas remaining inside is moved back to the adsorption tower 400
Characterized by adsorption and desorption type VOC recovery equipment.
According to claim 5,
The VOC storage unit 800
The recovery of the VOC in the form of gasoline
Characterized by adsorption and desorption type VOC recovery equipment.
A first step (S100) of introducing VOC gas containing VOC into the gas inlet 100;
A second step (S200) in which the condensed liquid generated while the VOC gas is moved through the pipe is separated from the knock-out drum 200;
A third step (S300) of sensing the pressure inside the knockout drum 200;
A fourth step (S400) of operating the blower 300 according to the internal pressure of the knock-out drum 200 sensed in the third step (S300);
A fifth step (S500) of moving the VOC gas from which the condensed liquid is separated from the knock-out drum 200 by the blower 300 to an adsorption tower 400;
Some of the plurality of adsorption towers 400 connected in parallel are installed on one side of the adsorption tower 400, and the valve 900_1 connected to the blower 300 is opened, and the VOC gas containing the VOC is released into the adsorption tower 400. The VOC is adsorbed on the activated carbon 410 installed inside the adsorption tower 400, and at the same time, the valve 900_2 installed on one side of the adsorption tower 400 and connected to the gas outlet 420 is opened, and the VOC is removed. The adsorption tower 400, in which gas is discharged to the outside and the VOC gas containing the VOC is not moved to the inside, is installed on one side of the adsorption tower 400 and a valve 900_3 connected to the air injection unit 430 is Air is moved from the outside to the inside of the adsorption tower 400, and at the same time, the vacuum pump 500 is operated, and the valve 900_4 installed on one side of the adsorption tower 400 and connected to the vacuum pump 500 is opened, and the adsorption tower ( 400) A sixth step (S600) in which the VOC adsorbed on the activated carbon 410 installed therein is converted into gaseous recovery gas and transferred to the C-VRU 600;
a seventh step (S700) of cooling and condensing the VOC of the recovery gas recovered in the sixth step (S600) in the C-VRU (600); and
The eighth step (S800) in which the VOC cooled and condensed in the seventh step (S700) is stored in the VOC storage unit 630
Adsorption and desorption type VOC recovery method characterized by.