KR20190044380A - Filter support apparatus of Volatile Organic Compounds Pre-treatment system - Google Patents

Abstract

The present invention relates to a filter support device for a volatile organic compound pretreatment system. By imparting a vibration function to the support device for supporting a cartridge unit for adsorbing volatile organic compounds from the polluted gas in the reaction part, more volatile organic compounds can be desorbed during a desorption process of the volatile organic compounds, thereby maximizing the adsorption/desorption performance of the cartridge unit.

Description

Technical Field The present invention relates to a filter support apparatus for a volatile organic compound pretreatment system,

The present invention relates to a filter support apparatus for a volatile organic compound pretreatment system, and more particularly to a filter support apparatus for supporting a volatile organic compound in a reaction unit, The present invention relates to a filter support apparatus for a volatile organic compound pretreatment system that maximizes the adsorption / desorption performance of a cartridge unit by allowing more volatile organic compounds to be desorbed.

The odor components generated in sewage treatment plants, pig farms, livestock wastewater treatment plants, slaughterhouses, food factories, and various chemical plants vary widely in composition of pollutants depending on the source and source of the pollutants. Major odor inducing substances include hydrogen sulfide and mercaptan Sulfur compounds, nitrogen compounds such as ammonia and amines, and volatile organic compounds (VOCs) or volatile sulfur compounds including benzene, toluene, ethylbenzene, and xylene.

Such odorous components are generally converted to water and carbon dioxide, and are generally removed. Currently, the odor gas treatment techniques currently used include physical and chemical deodorization methods such as activated carbon absorption method, chemical solution cleaning method, ozone oxidation method, , An activated sludge method, and a bio-filter.

These methods may be used alone or in combination of two or more depending on the treatment environment in which odor gas is to be removed. However, the physico-chemical deodorization method has problems of operating costs such as chemicals and material costs, Requires a lot of area and has a drawback in that a high power loss is required due to a high pressure loss.

In recent years, there has been a growing interest in a method for deodorizing charged microorganisms using a microorganism carrier capable of operating at a small cost in a small space among the biological deodorization methods at a low cost and having high deodorization efficiency.

The method for deodorizing a carrier-loaded microorganism is a method for removing odorous gas by introducing a malodorous gas into a packed column filled with a carrier immobilizing microorganisms. The microorganisms in the packed column are maintained by the energy generated by the decomposition of the malodorous gas and a small amount of nutrients. do. That is, the malodorous components are decomposed and removed by the cultured microorganism.

The biological method using microorganisms as described above has been mainly used for general wastewater treatment, but recently it has been applied to the field of odor removal and its utilization has been increasing.

However, in such a biological method, the biofilter is difficult to operate stably due to the characteristics of the biofilter utilizing limited microorganisms when the concentration of volatile organic compounds in the polluted gas is rapidly changed or the flow rate is fluctuated. Since the concentration and flow rate of such volatile organic compounds are frequently changed, there is a great difficulty in applying and operating the biofilter in the actual field.

In recent years, a pretreatment apparatus for adsorbing volatile organic compounds through filter fibers of an internal cartridge unit by receiving polluted gas, desorbing volatile organic compounds by a temperature change of the cartridge unit, and concentrating and discharging volatile organic compound concentrations of the internal pollutant gases The cartridge unit acting as a filter does not exhibit sufficient adsorption and desorption ability at a large amount of volatile organic compound discharge sites and has a short life span, a large volume, and a heavy weight, to be.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a supporting device for supporting a cartridge unit for adsorbing a volatile organic compound from a polluted gas in a reaction part, The present invention provides a filter support apparatus for a volatile organic compound pretreatment system that maximizes absorption / desorption performance of a cartridge unit by allowing desorption of a large amount of volatile organic compounds.

According to the present invention, a supporting device for supporting a cartridge unit for adsorbing a volatile organic compound from a polluted gas into a reaction part is provided with a vibration function, so that more volatile organic compounds can be desorbed in the desorption process of the volatile organic compound, A filter support apparatus for a volatile organic compound pretreatment system that maximizes adsorption / desorption performance is provided.

According to the present invention, a supporting device for supporting a cartridge unit for adsorbing a volatile organic compound from a polluted gas into a reaction part is provided with a vibration function, so that more volatile organic compounds can be desorbed in the desorption process of the volatile organic compound, And has an effect of maximizing the adsorption / desorption performance.

1 is a view for explaining a pretreatment apparatus for volatile organic compounds to which the present invention is applied.
2 is a view for explaining a cartridge unit to which the present invention is applied;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a filter support apparatus of a pretreatment system for a volatile organic compound according to the present invention will be described in detail with reference to the accompanying drawings.

The pretreatment apparatus for removing volatile organic compounds according to the present invention can be installed and operated in front of a filter apparatus for removing volatile organic compounds from an apparatus for discharging polluted gas containing volatile organic compounds (VOCs) And the volatile organic compounds in the polluted gas are concentrated and discharged at a constant concentration before the discharged pollutant gas is supplied to the filter.

The pretreatment apparatus for removing such volatile organic compounds includes a supply unit 100 for supplying a pollutant gas containing a volatile organic compound and a supply unit 100 for supplying the pollutant gas from the supply unit 100 to the filter fiber A reaction unit 200 for adsorbing volatile organic compounds through the reaction unit 232 and desorbing the volatile organic compounds by the temperature change of the cartridge unit 230 to concentrate and discharge the volatile organic compound concentration of the internal polluting gas, A discharge unit 400 for transferring and discharging the polluted gas whose concentration of the volatile organic compound is controlled from the supply unit 400 and the reaction unit 200, The control unit 300 controls the temperature of the cartridge unit 230 so that the concentration of the volatile organic compound becomes the target concentration concentration It may be configured to also.

The supply unit 100 is connected to a pollutant gas discharge port of the pollutant gas discharge facility to supply the pollutant gas to the reaction unit 200.

The discharge unit 400 discharges the polluted gas whose concentration of the volatile organic compound is adjusted to the target concentration concentration by the reaction unit 200 and preferably includes a filter unit 500 for removing volatile organic compounds from the polluted gas So that the pollutant gas can be supplied to the filter unit 500.

The reaction unit 200 has an internal space through which the pollutant gas can be introduced from the supply unit 100 and is operated under the external control of the control unit 300 to control the volatile organic compound concentration of the pollutant gas to a target concentration level Regulated and discharged.

The reaction unit 200 includes an intake fan 210 and an exhaust fan 270 for introducing the polluted gas into the reaction unit 200 and discharging the reaction gas to the outside of the reaction unit 200, A power supply line 240 connected to the cartridge unit 230 to supply a current and a temperature measuring unit 230 for measuring the temperature of the cartridge unit 230; And a concentration measuring unit 260 for measuring the concentration of the volatile organic compound in the pollutant gas in the reaction unit 200.

The suction fan 210 is installed at a connection part of the reaction part 200 with the supply part 100 and operates according to the control of the control part 300 to suck the polluted gas from the supply part 100. Although the suction fan 210 is shown in the drawings and described above as being installed at the connection part with the supply part 100 in the reaction part 200, It is possible to place it at any position as long as it can be introduced into the housing 200.

The exhaust fan 270 is installed at a connection portion with the exhaust unit 400 in the reaction unit 200 and operates according to the control of the control unit 300 to remove the pollutant gas from the reaction unit 200 from the exhaust unit 400, . Although the exhaust fan 270 is illustrated as being installed at the connection portion with the exhaust unit 400 from the reaction unit 200 in the drawings and the description above, It is possible to discharge the exhaust gas to the discharge unit 400 at any position.

A slot support 220 having a plurality of support holes 221 is installed in the inner space of the reaction unit 200 and the cartridge units 230 are inserted into the support holes 221 of the corresponding slot support 220. . The densities of the cartridge units 230 can be adjusted through the arrangement of the support holes 221, and the respective cartridge units 230 are preferably spaced apart from each other.

2, the cartridge unit 230 includes an insulating frame 231 having a predetermined space therein using an insulating material, and a filter fiber 232 wound around the insulating frame 231 A power supply line 231a made of a conductive material is provided at the upper and lower ends of the insulation frame 231 so that the power supply line 240 can be connected. In this heat transfer structure, when current is transmitted through the power line 240, the insulating frame 231 may be heated according to the amount of current to control the temperature of the filter fiber 232.

Here, the insulating frame 231 is preferably a mica board as a resistance material for electric current, but any material can be used as long as it is a heat-resistant resistance material.

The filter fiber 232 is preferably an activated carbon fiber (ACF). This activated carbon fiber is a fibrous adsorbent, fibrous activated carbon made by burning and reviving natural fiber, artificial organic material, and chemical fiber as a carrier. It has higher adsorption power than powder or granular activated carbon and can be regenerated easily at high temperature. It has a long lifetime and low maintenance cost compared to general activated carbon. Particularly, it is suitable as an adsorbent material for volatile organic compounds (VOCs) such as the present invention because of its large surface area, large adsorption capacity, fast adsorption and desorption rates, and excellent releasability. The filter fiber 232 is wound and fixed several times on the insulating frame 231, and the temperature of the filter fiber 232 can be received as it is heated.

The temperature measuring unit 250 may be a non-contact type infrared thermometer for measuring the temperature of the cartridge unit 230.

The concentration meter 260 is configured to measure the concentration of volatile organic compounds in the pollutant gas in the reaction unit 200, and may be composed of PID.

The volatile organic compound of the polluted gas that is sucked in the reaction part 200 will be adsorbed to the filter fiber 232 of the cartridge unit 230. When a current is applied by the power line 240 to increase the temperature of the cartridge unit 230, the volatile organic compounds adsorbed on the filter fibers 232 are desorbed. As the temperature is higher, Lt; RTI ID = 0.0 > 232 < / RTI > Accordingly, it is possible to control the desorption amount of the volatile organic compound through the temperature control of the cartridge unit 230, and as a result, the volatile organic compound concentration of the polluting gas in the reaction part 200 can be controlled. Particularly, the concentration of the volatile organic compound in the pollutant gas in the reaction part 200 can be adjusted to a predetermined target concentration, and the control to the target concentration can be performed by controlling the reaction part 200 of the control part 300 .

The control unit 300 includes an air volume controller 320 for controlling the operation of the intake fan 210 and the exhaust fan 270 of the reaction unit 200 and a control unit for controlling the current through the power supply line 240 to the cartridge unit 230 The controller 300 receives the measured value of the concentration of the volatile organic compound from the concentration meter 260 of the reaction unit 200 and controls the power controller 310 so as to achieve the target concentration concentration, A control unit 330 for controlling the temperature of the control unit 230 and controlling the air volume regulator 320 to discharge the pollutant gas having the volatile organic compound having the target concentration concentration, And an indicator 340 capable of monitoring the operation of the apparatus.

The power regulator 310 controls the current supply to each of the cartridge units 230 and adjusts the amount of current according to a preprogrammed control algorithm to control the temperature of the cartridge unit 230. [

The controller 330 receives the concentration value of the volatile organic compound in the reactor 200 from the concentration meter 260 and compares the concentration of the volatile organic compound in the reactor 200 with the target concentration concentration of the predetermined volatile organic compound, If the concentration of the volatile organic compound is lower than the target concentration, the amount of current applied to each of the cartridge units 230 through the power regulator 310 is increased to increase the temperature of the cartridge unit 230 so that more volatile organic compounds can be desorbed The concentration of the volatile organic compound in the reaction part 200 will be increased.

The controller 330 receives the concentration value of the volatile organic compound present in the reaction part 200 from the concentration meter 260 and compares the concentration value with the target concentration concentration of the predetermined volatile organic compound, When the concentration of the volatile organic compound in the cartridge unit 230 reaches the target concentration level, the current applied to each of the cartridge units 230 is interrupted through the power regulator 310 to lower the temperature of the cartridge unit 230, So that the concentration of the volatile organic compound in the reaction part 200 will be adjusted to the target concentration concentration.

As the process (current supply / cutoff) is repeated, the concentration of the volatile organic compound in the reaction unit 200 will be maintained at the target concentration concentration.

On the other hand, in the above-described volatile organic compound pretreatment system, the volatile organic compounds adsorbed in the desorption operation are not completely desorbed but are put into the adsorption operation again. If the complete desorption is not performed, the adsorption performance is lowered and the service life is also reduced.

According to the present invention, a vibrating function is imparted to a supporting device for supporting the corresponding cartridge unit 230 in the reaction part 200, and the physical vibrations promote the desorption of volatile organic compounds in the cartridge unit 230 .

As described above, an optimal embodiment has been disclosed in the drawings and specification. Although specific terms have been employed herein, they are used for purposes of illustration only and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: supply part 200: reaction part
210: Suction fan 220: Slot support
221: Support hole 230: Cartridge unit
231: Insulation frame 232: Filter fiber
240: power line 250: temperature meter
260: Concentration meter 270: Exhaust fan
300: control unit 310: power regulator
320: air volume regulator 330: controller
340: Indicator 400:
500:

Claims (1)

Characterized in that it is formed in a reaction part in which a cartridge unit is arranged and supports an internal cartridge unit for adsorbing a volatile organic compound from a polluted gas and physical vibration is applied to the cartridge unit to promote desorption of volatile organic compounds The filter support device of the system.

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