KR20180040009A - Removal system for VOCs - Google Patents

Abstract

Disclosed is a VOCs removal system which includes: a VOCs preprocessing unit where VOCs are adsorbed and detached in air including VOCs; a first processing unit which enables VOCs gas to be adsorbed to the VOCs preprocessing unit by moving air including VOCs to the VOCs preprocessing unit at one side and moves air from which VOCs are removed at the other side by being connected with the VOCs preprocessing unit at one side and at the other side; and a second processing unit which does not operate at least when the first processing unit operates, enables VOCs to be detached by supplying heated air to the VOCs preprocessing unit at one side and discharges only air by incinerating VOCs by adding heat to VOCs and heated air at the other side by being connected with the VOCs preprocessing unit at one side and at the other side. The present invention can be miniaturized, reduce installation costs, and reduce operation costs.

Description

VOCs removal system {Removal system for VOCs}

The present technology relates to a VOCs removal system.

In particular, in order to reduce the installation cost, reduce the operating cost, and reduce the installation area in the VOC removal system, it is necessary to perform a process of adsorbing and desorbing VOCs to a VOCs preprocessing unit, .

A domestic patent application No. 10-2014-0111089 discloses an invention relating to a VOCs removal system for a large painting factory.

VOCs stands for Volatile Organic Compounds, which means volatile organic compounds.

VOCs are hydrocarbon compounds that volatilize in the atmosphere and generate odor or ozone. They are carcinogens that cause damage to the nervous system through skin contact or breathing inhalation. Benzene, formaldehyde, toluene, xylene, ethylene, styrene, acetaldehyde, and the like.

VOCs are generated in automobile exhaust gas, and in the shipbuilding industry, they occur in large paint factories in shipyards.

Conventional VOCs removal systems or removal devices utilize a rotor to compress or supply air.

When using a rotor to remove VOCs, it was possible to remove VOCs, but problems such as an increase in installation area, an increase in installation cost, and an increase in operating expenses have arisen.

In particular, large-scale paint factories such as shipyards that discharge large amounts of low-concentration VOCs discontinuously have ineffective aspects of removing or removing VOCs using such a rotor.

Accordingly, there is a need for a new VOCs removal system which is equipped with a VOCs preprocessor, which is suitable for removing VOCs generated in a large paint factory of a shipyard, and that can efficiently utilize the VOCs preprocessor.

Domestic open patent application number "10-2014-0111089" " VOCs removal system of large paint factory "

It is an object of the present invention to provide a VOCs removal system suitable for a large-scale paint factory of a shipyard which discharges large-volume low-concentration VOCs discontinuously.

An object of the present invention is to provide a VOCs removal system suitable for a large painting factory of a shipyard having one VOCs preprocessing unit for removing VOCs.

It is an object of the present invention to provide a system for removing VOCs suitable for a large painting factory of a shipyard that realizes miniaturization, reduction of installation cost, reduction of operating costs, and the like.

The technical object of the present invention is not limited to the above-mentioned technical objects and other technical objects which are not mentioned can be clearly understood by those skilled in the art from the following description will be.

The VOCs removal system according to an exemplary embodiment of the present invention includes a VOCs pretreatment unit capable of adsorbing and desorbing VOCs from air containing VOCs, air containing VOCs at one side and one side of the VOCs pretreatment unit, VOCs pre-processing unit to adsorb VOCs gas to the VOCs preprocessing unit and the other side to move the VOC-free air, at least when the first process unit is operated, the VOCs pre- And a second processing unit connected to the other side to supply the heated air to the VOCs preprocessing unit so that the VOCs are desorbed from the one side and the heated air and the VOCs are heated by incinerating the VOCs.

Here, in the VOCs removal system according to an embodiment of the present invention, the VOCs pretreatment unit includes activated carbon having a honeycomb structure.

The first process unit includes a first suction fan for sucking air containing the VOCs, a first suction valve installed between the suction fan and the VOCs preprocessing unit for opening and closing the passage, And a first discharge valve provided between the first discharge port and the VOCs preprocessing section for opening and closing the passage.

Here, the second process unit may include a second suction fan for sucking air, an air heating device for heating the air supplied from the second suction fan, a valve provided between the air heating device and the VOCs preprocessing unit, A second suction valve for closing the VOCs, a second suction valve for closing the VOCs, and an incinerator for burning the VOCs by applying heat to the heated air including the VOCs discharged from the VOCs preprocessor, and a valve installed between the incinerator and the VOCs pre- And a second outlet for discharging the air in which the VOCs are incinerated in the incineration burner.

Here, when the first suction fan is operated and the adsorption process of opening the passages of the first suction valve and the first discharge valve is performed, the second suction fan performs an operation, and the second suction fan And the second suction valve and the second discharge valve open the passage to remove the VOCs adsorbed in the VOCs preprocessing section and the incineration process section is operated to remove the air containing the VOCs The desorption process for heating and burning the VOCs is operated not to be performed so that the adsorption process and the desorption process are alternately performed so as not to overlap each other at least.

The first suction passage, which is connected to the first suction valve and the VOCs preprocessing section, is shared by a second suction passage connected to the second suction valve and the VOCs preprocessing section, and the first discharge valve and the VOCs pre- And the passage is also shared by the second discharge valve and the second discharge passage connected to the VOCs preprocessing section.

Here, the first processing unit includes a first filter unit for filtering impurities into air containing VOCs sucked from the first suction fan.

Here, the second process unit may include a second filter unit for filtering impurities of the air sucked in the second suction fan.

Here, a heat exchange unit is provided between the incinerator and the second outlet, between the incinerator and the second outlet, and the heat of the heated air, in which the VOCs heated in the incinerator are incinerated, To preheat air.

Here, the VOCs removal system is connected to the first suction fan, the first suction valve, and the first discharge valve, and the second suction fan, the air heating device, the second suction valve, the second discharge valve, The control unit may further include a first suction fan, a first suction valve, and a second suction fan, which receive the first signal or the second signal and output the first signal, the second signal, and the third signal, The operation in which the first discharge valve is performed and the operation in which the second suction fan, the air heater, the second suction valve, the second discharge valve, and the incineration process are performed operate inversely, and when the third signal is received, .

The VOCs removal system of the present invention according to one embodiment of the present invention, which is formed through the above-described construction, is optimized for a large-sized paint factory of a shipyard which discontinuously discharges large-volume low-concentration VOCs.

The VOCs removal system of the present invention, which is formed through the above-described configuration according to an embodiment of the present invention, can be miniaturized since the rotor is omitted and only one VOCs preprocessor is provided.

The system for removing VOCs according to one embodiment of the present invention, which is formed through the above-described configuration, can reduce the installation cost and the operation cost.

1 is a view illustrating a system for removing VOCs according to an embodiment of the present invention.
FIG. 2 shows an operation diagram of a VOCs removal system according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to exemplary drawings. However, this is not intended to limit the scope of the invention.

It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In addition, the size and shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms specifically defined in consideration of the constitution and operation of the present invention are only for explaining the embodiments of the present invention, and do not limit the scope of the present invention.

1 is a view illustrating a system for removing VOCs according to an embodiment of the present invention.

The VOCs removal system according to an embodiment of the present invention includes a first cleaner and a second cleaner.

Further, it includes a VOCs preprocessing unit 10.

Here, the VOCs preprocessing unit 10 performs a process of adsorbing or desorbing VOCs.

The adsorption and desorption of VOCs can be realized through activated carbon of honeycomb structure in one embodiment.

That is, in the process of passing air containing VOCs through the activated carbon of the honeycomb structure, the VOCs are adsorbed on the activated carbon of the honeycomb structure and the VOCs can be desorbed from the activated carbon by passing air above the set activated carbon.

The above scheme can be implemented as an embodiment.

The VOCs removal system according to an embodiment of the present invention can eliminate the rotor through the above-described method and can remove VOCs by utilizing one VOCs preprocessor 10, Reduction of the installation area, and the like can be realized.

The first process unit includes a first suction fan 100, a first suction valve 130, a first discharge port 150, and a first discharge valve 140.

The first suction fan 100 serves to supply air including VOCs generated in the painting factory to the VOCs removal system.

The first suction valve 130 is installed between the first suction fan 100 and the VOCs preprocessing unit 10.

The first suction valve 130 serves to open and close a passage between the first suction fan 100 and the VOCs preprocessing unit 10.

Therefore, according to the operation of the first suction valve 130, the air containing the VOCs can be supplied or blocked to the VOCs preprocessing unit 10.

The first outlet 150 serves to discharge the air from which VOCs have been removed by the VOCs preprocessing unit 10.

The first outlet 150 may be, but is not limited to, a discharge fan, by way of example.

The first discharge valve 140 is installed between the VOCs preprocessing unit 10 and the first discharge port 150.

The first discharge valve 140 serves to open and close the passage between the VOCs preprocessing unit 10 and the first discharge port 150.

Accordingly, the VOCs removed from the VOCs preprocessing unit 10 can be discharged to the first outlet 150 or shut off according to the operation of the first discharge valve 140.

The first process unit formed through the above structure is connected to the VOCs preprocessing unit 10 at the other side to transfer the air containing the VOCs to the VOCs preprocessing unit 10 to adsorb the VOCs, And to move it.

The second process unit includes a second suction fan 200, an air heating device 220, a second suction valve 230, an incineration hole 250, a second discharge valve 240 and a second outlet 270 .

The second suction fan 200 serves to suck air.

Here, the second suction fan 200 is not air containing at least VOCs sucked in.

The second processing section is not activated when at least the first processing section is operated.

That is, when the first process unit is operated and the VOCs are removed from the VOCs preprocessing unit 10 through the VOCs preprocessing unit 10, the second process unit is not operated.

To be precise, the second suction valve 230 and the second discharge valve 240 do not open the respective passages.

The air heating device 220 heats the air supplied from the second suction fan 200.

Here, the temperature at which the air heating apparatus 220 heats the air must be heated to a temperature at which the adsorbed VOCs are desorbed when the heated air passes through the VOCs preprocessing unit 10.

The second suction valve 230 is installed between the air heating unit 220 and the VOCs pre-processing unit 10.

The second suction valve 230 serves to open and close the passage through which the air heated by the air heating device 220 can be moved to the VOCs preprocessing unit 10.

The incinerator 250 serves to incinerate the VOCs by applying heat to the heated air containing the VOCs desorbed from the VOCs preprocessor 10.

The second discharge valve 240 is provided between the incineration burner unit 250 and the VOCs pre-treatment unit 10 to open or close the passage through which heated air containing VOCs can be transferred to the incineration burner unit 250 It plays a role.

The second outlet 270 discharges the air in which the VOCs are incinerated.

Here, the second outlet 270 may also be configured as a second outlet fan as in the embodiment of the first outlet 150.

The second process unit having the above configuration is connected to the VOCs preprocessing unit 10 at one side and the other side to supply the heated air to the VOCs preprocessing unit 10 so that the VOCs are desorbed and the VOCs are incinerated to discharge only the air.

As described above, the VOCs removal system including the first and second processing units share one VOCs preprocessing unit 10 without simultaneously performing the processes of the first and second processing units, and the rotor is omitted And can be realized with miniaturization.

The system for removing VOCs according to an embodiment of the present invention includes a first suction passage connected to the first suction valve 130 and a VOCs pre-process, a second suction valve 230 connected to the VOCs preprocessing section 10, The pathway can be shared.

The first discharge passage connected to the first discharge valve 140 and the VOCs preprocessor 10 according to an embodiment of the present invention includes a second discharge valve 240 connected to the VOCs preprocessing unit 10, It can be shared with the aisle.

That is, a part of the first suction passage and the second suction passage may be formed as "ㅓ" and a part of the first suction passage and the second suction passage may be shared.

Here, according to the embodiment, the first suction passage and the second suction passage may be formed as one.

The features of the first suction passage and the second suction passage as described above can be implemented by applying to the first discharge passage and the second discharge passage.

The first process unit may include a first filter unit.

The first filter unit includes a mist removing filter and a first dust removing filter.

The air absorbed by the first suction fan 100 may be air containing a plurality of impurities including VOCs, and the impurities are filtered through the first filter unit (double filter).

The first filter unit may be installed between the first suction fan 100 and the first suction valve 130.

The mist removing filter and the first dust removing filter of the first filter unit can be installed between the first suction fan 100 and the first suction valve 130 and have a single body, A filter can be installed.

The first filter unit serves to prevent impurities from flowing into the VOCs preprocessing unit 10.

Therefore, various fine impurities, large-size impurities, and the like are not introduced into the VOCs preprocessor 10, so that the lifetime of the VOCs preprocessor 10 is increased and the efficiency can be increased.

The second process unit may include a second filter unit.

Here, the second filter portion may include a second dust filter.

The second filter portion is installed between the second absorption fan and the air heating device 220.

The second filter unit filters the impurities contained in the air absorbed by the second absorption fan.

When the air absorbed by the second absorption fan contains impurities and the heated air without any impurities is introduced into the VOCs preprocessing unit 10, the life of the VOCs preprocessing unit 10 is reduced, Can be reduced.

In order to prevent the above-described problems, the second process unit may include a second filter unit.

In the above description, the second filter unit is limited to only the second dust filter. However, the second filter unit is not limited to the second filter unit, It may be formed by including a mist removing filter as in the case of the first embodiment.

In addition, the VOCs removal system of the present invention may be provided with a heat exchange unit 260.

The heat exchanging part 260 may be installed between the second suction fan 200 and the air heating device 220 and between the incineration hole 250 and the second outlet 270.

That is, the air that flows through the second suction fan 200 and moves to the air heater 220 passes through the heat exchanger 260 and is supplied with heat from the incinerator 250 to remove the VOCs Air passes through the heat exchanging unit 260 as well.

The passage of the first process unit passing through the heat exchanging unit 260 may be formed by bending the heat exchanging unit 260 and the passage of the second process unit passing through the heat exchanging unit 260 may be bent .

Therefore, the temperature of the heated air of the second process unit can be transferred from the heat exchanger 260 to the air of the first process unit.

Therefore, the air supplied through the first suction fan 100 receives the heat of the high-temperature air discharged from the incinerator 250 through the heat exchanger 260 before the air heater 220, .

This is because the temperature of the hot air of the second process unit is transferred to the air of the first process unit without waste, and the preheating is performed, so that the energy efficiency can be increased.

FIG. 2 shows an operation diagram of a VOCs removal system according to an embodiment of the present invention.

The VOCs removal system formed through the above configuration is realized through the adsorption process and the desorption process as shown in FIG.

Here, the adsorption process is a process in which VOCs are adsorbed to the VOCs preprocessor 10, and the first suction fan 100 operates, and the first suction valve 130 and the first discharge valve 140 operate, The second suction fan 200 does not operate and the air heating device 220 stops heating and the second suction valve 230 and the second discharge valve 240 close each of the passages , And the incineration hollow part 250 also stops the operation.

Here, in the desorption process, the VOCs are removed from the VOCs preprocessor 10, the second suction fan 200 operates, the air heating device 220 performs the heating operation, and the second suction valve 230 The first suction valve 130 and the first discharge valve 140 are closed by closing the respective passages of the first suction valve 130 and the second discharge valve 140. [ .

That is, the adsorption process is a process of performing the role assigned to each of the first hollow portions, and the desorption process is a process of performing the role assigned to each of the second hollow portions.

As can be seen in Fig. 2, the adsorption process and the desorption process are performed so that the performance of the process is not at least superimposed.

That is, the process is repeatedly performed in the order of adsorption process, desorption process, shutdown, adsorption process, desorption process, and shutdown.

Here, the above process can be implemented through the control unit 300.

The system for removing VOCs according to an embodiment of the present invention includes a control unit 300.

1, the control unit 300 is connected to the first suction fan 100, the first suction valve 130, and the first discharge valve 140, and the second suction fan 200, The second suction valve 230, the second discharge valve 240, and the incinerator unit 250, as shown in FIG.

The controller 300 outputs the first signal and the second signal.

Here, when each valve receives the first signal of the controller 300, it operates to perform an adsorption process.

That is, according to the first signal of the controller 300, the first suction fan 100 operates to suck air containing VOCs, and the first suction valve 130 and the first discharge valve 140 open the passage The second suction fan 200 and the second discharge valve 240 are operated to stop the operation of the air heating apparatus 220 and the air heating apparatus 220 does not perform the operation of heating the air, The passage is closed, and the incineration hole portion 250 does not perform the incineration operation.

Further, when each valve receives the second signal of the control unit 300, it operates to perform the desorption process.

That is, the second suction fan 200 operates according to the second signal of the controller 300, the air heater 220 performs the operation of heating the air, and the second suction valve 230 and the second discharge The valve 240 opens the passage and the incineration hole 250 performs the incineration operation and the first suction fan 100 stops operating and the first suction valve 130 and the first discharge valve 140 ) Closes the passageway.

In addition, the control unit 300 may further output the third signal.

Here, each valve that receives the third signal of the control unit 300 closes each passage.

In other words, the first suction valve 130 and the first discharge valve 140 close the passage and the second suction valve 230 and the second discharge valve 240 also close the passage in accordance with the third signal of the control unit 300, Lt; / RTI >

According to the first signal, the second signal, and the third signal of the controller 300, the VOCs removal system of the present invention can alternately perform the adsorption process, the desorption process, and the operation condition.

The VOCs removal system according to one embodiment includes a VOCs preprocessing unit 10 instead of an adsorption / desorption device including a conventional rotor, so that the VOCs generated after the coating operation of the painting factory of the shipyard is pre- VOCs can be adsorbed and desorbed through the portion 10 to lower the concentration of VOCs in the coating plant.

For example, when painting is performed by the painting factory and air containing VOCs is generated, the controller 300 outputs a first signal to perform an adsorption process so as to adsorb VOCs to the VOCs preprocessor 10 To reduce the concentration of VOCs in the coating plant.

When the concentration of the VOCs in the coating plant is lowered, the controller 300 outputs the second signal to perform the desorption process.

As described above, the desorption process is a process in which air containing no VOCs is sucked and heated and supplied to the VOCs preprocessing unit 10 to remove the VOCs, incinerate the VOCs, and discharge the regenerated air.

When the desorption process is completed, the operation of removing the VOCs is stopped.

Thereafter, when the coating plant again performs painting work and air containing VOCs is generated, the above-described processes are performed again in order.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

10: VOCs preprocessing unit 100: first suction fan
110: mist removing filter 120: first dust removing filter
130: first suction valve 140: first discharge valve
150: first outlet 200: second suction fan
210: second dust removing filter 220: air heating device
230: second suction valve 240: second discharge valve
250: incineration hole 260: heat exchanger
270: second outlet 300:

Claims (10)

A VOCs pretreatment unit capable of adsorbing and desorbing VOCs from air containing VOCs;
A VOCs pretreatment unit connected to one side of the VOCs preprocessing unit for moving air containing VOCs to the VOCs pretreatment unit so that the VOCs gas is adsorbed to the VOCs pretreatment unit and the VOCs removed air from the other side;
The VOCs are not activated when at least the first process unit is operated and connected to the VOCs preprocessing unit at one side and the other side to supply the heated air to the VOCs preprocessing unit so that the VOCs are desorbed and the heated air and VOCs A second burner for burning only the air by burning the VOCs by applying heat;
The VOC removal system comprising: The method according to claim 1,
The VOCs pre-
Containing activated carbon with honeycomb structure
Characterized in that the VOCs removal system comprises: The method according to claim 1,
The first processing unit includes:
A first suction fan for sucking air containing the VOCs, a first suction valve installed between the suction fan and the VOCs preprocessing unit for opening and closing the passage,
And a first discharge port for discharging the air from which the VOCs have been removed and a first discharge valve provided between the first discharge port and the VOCs preprocessing section for opening and closing the passage
Characterized in that the VOCs removal system comprises: The method of claim 3,
The second processing unit,
An air heating device for heating the air supplied from the second suction fan, a second suction valve installed between the air heating device and the VOCs preprocessing part for opening and closing the passage, ,
A second exhaust valve installed between the incineration burner and the VOCs pretreatment unit to open and close the passage, and a second exhaust valve installed between the incinerator and the VOCs pretreatment unit to open and close the passage, VOCs in the incinerator include a second outlet for discharging incinerated air
Characterized in that the VOCs removal system comprises: 5. The method of claim 4,
When the first suction fan is operated and an adsorption process is performed in which the passages of the first suction valve and the first discharge valve are opened,
The second suction fan performs an operation and the air heating device for heating the air sucked through the second suction fan heats the air and the second suction valve and the second discharge valve open the passages, And the desorption process for burning the VOCs by heating the air containing the VOCs is operated so as not to be performed
Wherein the adsorption step and the desorption step are alternately performed so as not to overlap each other at least
Characterized in that the VOCs removal system comprises: 5. The method of claim 4,
The first suction passage connected to the first suction valve and the VOCs preprocessing section is shared with the second suction passage connected to the second suction valve and the VOCs preprocessing section,
The first discharge passage connected to the first discharge valve and the VOCs preprocessing section is also shared with the second discharge passage and the second discharge passage connected to the VOCs preprocessing section
Characterized in that the VOCs removal system comprises: 5. The method of claim 4,
The first processing unit includes:
And a first filter portion for filtering impurities into air containing VOCs sucked in the first suction fan
Characterized in that the VOCs removal system comprises: 5. The method of claim 4,
And the second process unit includes a second filter unit for filtering impurities of the air sucked in the second suction fan
Characterized in that the VOCs removal system comprises: 5. The method of claim 4,
A heat exchanger is provided between the incinerator and the second outlet, between the incinerator and the second outlet,
And the heat of the heated air in which the VOCs heated by the incineration burner is burned is transferred to the air sucked from the second suction fan to preheat
Characterized in that the VOCs removal system comprises: 5. The method of claim 4,
The VOCs removal system
A first suction valve connected to the first suction fan, a first suction valve, and a first discharge valve,
And a control unit connected to the second suction fan, the air heater, the second suction valve, the second discharge valve, and the incinerator unit 250,
The control unit outputs a first signal, a second signal, and a third signal,
The first suction fan, the first suction valve, and the first discharge valve, which receive the first signal or the second signal, and the second suction fan, the air heater, the second suction valve, the second discharge valve, The operation in which the process section is performed is reversed
If the third signal is received, stopping the operation
Characterized in that the VOCs removal system comprises:

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