KR20110038360A - Absorption tower of two-bed type including fiborous activated carbon - Google Patents

Abstract

PURPOSE: A 2-bed type adsorption tower apparatus is provided to reduce the installation area by installing two adsorption towers in one body, and to prevent the subsidence and the flowing of activated carbon by using fibrous activated carbon. CONSTITUTION: A 2-bed type adsorption tower apparatus comprises the following: a 2-bed adsorption tower(200) formed with first and second beds(210,210`) for performing desorption and adsorption processes by turns; non-woven fabric filters(300,300`) formed on the lower sides of the first and second beds; fibrous activated carbon(400,400`) arranged in a zigzag type on the upper side of the non-woven fabric filters; hot air supplying pipe(500) formed on the upper side of the fibrous activated carbon; an inhaling pipe(600) inhaling desorbed volatile organic compounds; air supply dampers(700,700`) sealing a lower side space unit of the inhaling pipe; and an exhaust dampers(710,710`).

Description

Absorption tower of two-bed type including fiborous activated carbon}

The present invention relates to an adsorption tower, and more specifically, two reaction tanks capable of adsorption and desorption are integrally formed in the adsorption tower, and in the adsorption tower, fibrous activated carbons are arranged in a zigzag shape, so that the volatile organic compounds have high removal efficiency of volatile organic compounds. The present invention relates to a two-bed adsorption tower in which activated carbon is embedded.

In general, an automobile painting booth or other various painting facilities used to paint automobiles and their accessories in an automobile repair shop or a transportation company alternates painting and drying work on the goods. In addition to the paint mist that is scattered in the process, the solvent of the paint evaporates into the atmosphere during the drying process of the painted article, so that various volatile organic compounds (VOCs) such as toluene contain a large amount in the air inside the coating chamber. do. Most of the volatile organic compounds (VOCs) are irritating and emit unpleasant odors even at low concentrations. Legal discharge regulations are in place for the discharge facility.

There have been various methods of treating volatile organic compounds such as adsorption method, biological treatment method and catalytic combustion method, but it costs hundreds of millions of dollars except simple adsorption method, which is difficult to apply in reality. there was.

In addition, Korean Utility Model Registration No. 20-0337918 has been applied for an adsorption tower attached to a direct hot air spray type desorption device inside an activated carbon layer.

This is because there is a problem that the settlement of the activated carbon, that is, compaction phenomenon due to the flow activity as installed vertically using the granular activated carbon.

In addition, Korean Patent No. 10-0490140 'Volatile Organic Compound Treatment Equipment for Coating Equipment' uses granular granular activated carbon horizontally to prevent settlement but ultimately prevents flow phenomenon.

In addition, granulated activated carbon is a granular crystal (approximately 1 to 3 mm), and thus heat is hardly transferred to the inside of the molecule when hot air is supplied. .

In the related art, two adsorption towers have been known to proceed in a manner of adsorbing one while adsorbing one, so that continuous operation is possible, but these two adsorption towers are installed separately and require a lot of installation space. Since additional facilities according to the adsorption tower had to be installed separately, there was a problem in that the installation cost is high.

An object of the present invention is to provide a two-bed adsorption tower in which the two adsorption towers of the adsorption and desorption method are installed in a single unit rather than the two adsorption towers of the adsorption and desorption method.

It is also to provide a two-bed adsorption tower in which fibrous activated carbon is embedded to prevent the flow phenomenon of activated carbon by using fibrous activated carbon and to arrange in a zigzag form to maximize the contact area with volatile organic compounds.

In order to achieve the above object, the two-bed adsorption tower in which the fibrous activated carbon of the present invention is embedded is composed of first and second beds 210 and 210 'divided into two parts, and the first and second beds 210 and 210'. ) Is a two-bed adsorption tower 200 alternately proceeds to desorption and adsorption; nonwoven filter (300,300 ') formed in the lower portion of the first bed 210 and the second bed 210', respectively; the nonwoven filter (300,300) ') Formed on top of the fibrous activated carbon (400,400') arranged in a zigzag shape; formed on the upper side of the fibrous activated carbon (400,400 ') hot air supply pipe 500 for supplying hot air of 70 ~ 90 ℃; A suction pipe 600 formed at a lower side of the suction pipe 600 to suck and remove a volatile organic compound formed at a lower side of the suction pipe 600; and an air supply damper 700 and 700 'to open and close a lower space of the suction pipe 600; It is formed on the top of the hot air supply pipe 500 of the hot air supply pipe 500 Exhaust dampers 710 and 710 'that open and close the upper space; Characterized in that it comprises a.

According to a preferred embodiment, the zigzag-shaped fibrous activated carbon (400, 400 ') is arranged above the fibrous activated carbon (410,410') is characterized in that it is additionally installed.

According to a preferred embodiment, the first and second beds (210, 210 ') by installing a differential pressure gauge (800,800'), respectively, characterized in that it is periodically informed to replace the fibrous activated carbon (400,400 ').

According to a preferred embodiment, the nonwoven filter 300, 300 'is characterized in that it comprises a nonwoven filter 310,310' arranged in a horizontal manner and nonwoven filter 320,320 'arranged in a zigzag form.

According to the above problem solving means, the present invention does not have two adsorption towers installed in a separate type, but is installed in one piece, thereby reducing the installation area and maintaining a simple maintenance.

In addition, the use of fibrous activated carbon prevents the settlement and flow of activated carbon, and arranges them in a zigzag form to maximize the contact area with the volatile organic compounds, thereby improving the removal rate of the volatile organic compounds.

 Hereinafter, with reference to the accompanying drawings, it will be described in more detail with respect to the two-bed adsorption column embedded in the fibrous activated carbon of the present invention.

1 is a device diagram of a two-bed adsorption tower embedded with fibrous activated carbon according to a preferred embodiment of the present invention. Referring to Figure 1, the two-bed adsorption tower embedded in the fibrous activated carbon of the present invention is a two-bed adsorption tower 200, nonwoven filter (300, 300 '), fibrous activated carbon (400, 400'), hot air supply pipe 500, suction pipe 600 ), Air supply dampers 700 and 700 ', exhaust dampers 710 and 710', differential pressure gauges 800 and 800 ', and the like.

First, the two-bed adsorption tower 200 will be described.

The two-bed adsorption tower 200 is composed of first and second beds 210 and 210 'in which one adsorption tower 200 is divided into two parts, and the first and second beds 210 and 210' are alternately desorbed and adsorbed. That's how it works.

The interior of the adsorption tower 200 is partitioned by the partition wall 220, while the adsorption work proceeds in the first bed 210, the desorption proceeds in the second bed 210 'can proceed without stopping the painting work. .

In addition, two adsorption towers capable of adsorption and desorption are not installed in a separate type, but are easily installed and maintained as a single unit in one adsorption tower 200.

The two-bed adsorption tower 200 is generally used in automotive booths that generate a lot of volatile organic compounds. In addition, the two-bed adsorption tower 200 may be applied to any kind of equipment or apparatus requiring treatment of volatile organic compounds. Of course.

Next, the nonwoven fabric filters 300 and 300 'will be described.

The nonwoven fabric filters 300 and 300 ′ are formed under the first bed 210 and the second bed 210 ′, respectively.

The nonwoven fabric filter 300, 300 'primarily filters the contaminated air flowing from the coating equipment and filters out various foreign matters or dusts except volatile organic compounds.

According to a preferred embodiment, it is possible to stack and install nonwoven filters 320 and 320 'arranged in a zigzag manner against the nonwoven filters 310 and 310' arranged horizontally.

Next, the fibrous activated carbon (400,400 ') will be described.

The fibrous activated carbon 400, 400 ′ is formed on the nonwoven filter 300, 300 ′ and arranged in a zigzag shape.

Fibrous activated carbon (400,400 ') serves to remove volatile organic compounds (V.O.Cs) from the air introduced from the coating facility (100).

Fibrous activated carbon (400,400 ') is made by firing and reviving natural fibers or artificial organic chemical fibers as a raw material, and there is no fear that activated carbon will flow because graphite crystals are accumulated.

In addition, the average crystals of the fibrous activated carbon (400, 400 ') are finer particles than the granular activated carbon, so the contact area is wide and the adsorption and desorption rate is high.

In general, the size of the fibrous activated carbon is about 10 ~ 20㎛, granulated activated carbon is 1 ~ 3mm it can be seen that the adsorption and desorption rate of the fibrous activated carbon is 10 times faster than the granular activated carbon.

In addition, unlike granulated activated carbon of granular type, the average crystals are fine, so that it is difficult to contain heat in the molecule during hot air supply, so that there is little fear of spontaneous ignition even if the natural wind or air flow changes slightly.

In the present invention, the plate-shaped fibrous activated carbon (400,400 ') is arranged in a zigzag form because carbon is accumulated in the fibrous skeleton and has no flow, so that the contact area with volatile organic compounds is maximized.

Looking in more detail, to produce a fibrous activated carbon (400,400 ') accumulated graphite crystals on the non-woven fabric type, and to be inclined to each other, four fibrous activated carbon (400,400') per bed arranged in a zigzag form.

However, the material and the number of arrangement of the fibers used can be easily changed according to the shingles rate and the size of the adsorption tower.

According to a preferred embodiment, the fibrous activated carbons 410 and 410 'arranged in a horizontal manner may be further installed above the fibrous activated carbons 400 and 400' stacked in a zigzag manner.

Next, the hot air supply pipe 500 will be described.

The hot air supply pipe 500 is formed on the upper side of the fibrous activated carbon (400, 400 ') to supply hot air of 70 ~ 90 ℃.

The hot air supply pipe 500 is a device for supplying hot air to desorb the volatile organic compounds adsorbed on the fibrous activated carbon (400,400 ').

In the case of granular activated carbon, the granular activated carbon needs to be supplied with heat of about 120 to 150 ° C. in order to be formed to a sufficient size of the average crystal and heated to the inside of the molecule. Because of the fine contact area is large, it can be sufficiently heated under hot air of 70 ~ 90 ℃.

Therefore, there is no fear of fire due to overheating during hot air supply of the hot air supply pipe 500, and no separate cooling facility is required.

Next, the suction pipe 600 will be described.

The suction pipe 600 is a passage through which the volatile organic compounds desorbed formed at the lower side of the fibrous activated carbon 400 and 400 'are sucked in.

In the present invention, the suction pipe 600 is installed on each bed (210, 210 '), respectively, and is connected to the suction fan 620 fixed to the outside of the adsorption tower (200).

During the desorption reaction, the volatile organic compounds sucked through the suction pipe 600 are supplied to the heater 630 and the catalytic reactor 640 through the suction fan 620.

Since the reaction in which the volatile organic compound supplied to the catalytic reactor 640 is finally oxidized and removed is a general reaction, a description thereof will be omitted.

Next, the air supply dampers 700 and 700 'and the exhaust dampers 710 and 710' will be described.

The air supply dampers 700 and 700 'are formed at the lower side of the suction pipe 600 to open and close the lower space of the suction pipe 600, and the exhaust dampers 710 and 710' are formed at the upper side of the hot air supply pipe 500. It is in charge of opening and closing the upper space portion of the hot air supply pipe (500).

That is, the air supply dampers 700 and 700 'and the exhaust dampers 710 and 710' are a kind of doors installed horizontally so that adsorption and desorption operations are alternately performed in the first bed 210 and the second bed 210 '. It is a device for.

For example, in order for the adsorption operation to proceed in the second bed 210 ', the air supply damper 700' and the exhaust damper 710 'formed on the second bed 210' are both opened and the first bed 210 is opened. The air supply damper 700 and the exhaust damper 710 formed in the) both close.

As a result, the air supply flowing from the painting installation 100 is supplied only to the second bed 210 'and filtered through the nonwoven filter 300' and the fibrous activated carbon 400 'and discharged through the exhaust pipe 920.

While the adsorption operation is performed in the second bed 210 ′, the air supply damper 700 and the exhaust damper 710 formed in the first bed 210 are both closed and no more air supply flows.

In the first bed 210, hot air is supplied by the hot air supply pipe 500 to perform desorption of the fibrous activated carbon 400.

Next, the differential pressure gauges 800 and 800 'will be described.

The differential pressure gauges 800 and 800 'are installed in the first and second beds 200 and 200', respectively, and periodically replace the fibrous activated carbons 400 and 400 'by measuring the pressure between the fibrous activated carbons 400 and 400' with an analog or digital pressure gauge. Tells.

Next, an embodiment of the operation of the two-bed adsorption tower 200 in which the fibrous activated carbon of the present invention is embedded will be described.

In the painting chamber 100, volatile organic compounds, paint mist, and the like are generated during the spray coating.

The air inside the painting chamber 100 is introduced into the two-bed adsorption tower 200 through the discharge pipe (not shown) of the painting facility.

After sufficient time passes, the air supply damper 700 'and the exhaust damper 710' of the second bed 210 'are opened and the air supply damper 700 and the exhaust damper 710 of the first bed 210 are closed. The internal air of the painting chamber 100 is introduced only into the second bed 210 '.

The inside air of the coating room 100 introduced into the second bed 210 'passes through the nonwoven filter 300' installed at the lower side of the second bed 210 ', and most foreign substances such as paint mist are filtered out.

Next, most of the volatile organic compounds are adsorbed through the fibrous activated carbon 400 'installed in a zigzag shape, and the volatile organic compounds are adsorbed close to zero while passing through the activated carbon 410' installed horizontally.

Next, the filtered air is discharged out of the adsorption tower 200 through the exhaust fan 900.

Meanwhile, the desorption operation is performed in the first bed 210 while the adsorption operation is performed in the second bed 210 '.

In other words, the volatile organic compounds accumulated from the fibrous activated carbon 400 sufficiently adsorbed before are desorbed and finally removed.

The hot air supply pipe 500 operates the hot air supply fan 520 and the hot air heater 530 to inject desorption hot air (80 ° C.) through the hot air supply hole 510.

The volatile organic compound is desorbed from the fibrous activated carbon 400 and sucked through the suction pipe 600, and is supplied to the catalytic reactor 640 through the suction fan 14 and the heater 630.

The volatile organic compound supplied to the catalytic reactor 40 is finally oxidized and then discharged into the exhaust through the exhaust pipe 920.

As the adsorption and desorption operations proceed continuously, about 98% of the volatile organic compounds in the pottery 100 are removed.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and in the technical field to which the present invention pertains that substitutions, modifications, and conversions can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

1 is a device diagram of a two-bed adsorption tower embedded with fibrous activated carbon according to a preferred embodiment of the present invention.

 <Description of the symbols for the main parts used in the drawings>

100: Spray booth

200: 2-bed adsorption tower

210: first bed

210 ': 2nd bed

220: partition wall

300,300 ': non-woven filter

310,310 ': Nonwoven filter arranged horizontally

320,320 ': Zig-zag nonwoven filter

400,400 ': Zigzagally arranged fibrous activated carbon

410,410 ': Horizontally arranged fibrous activated carbon

500: hot air supply pipe

510: hot air supply hole

520: hot air heater

530: hot air fan

600: suction pipe

610: suction hole

620: suction fan

630: heater

640: catalytic reactor

700,700 ': Air supply damper

710,710 ': exhaust damper

800,800 ': differential pressure gauge

900: exhaust fan

910 exhaust motor

920 exhaust pipe

Claims (4)

In the device for removing volatile organic compounds, The inside of the adsorption tower is composed of first and second beds 210 and 210 'divided into two parts, and the first and second beds 210 and 210' are two-bed adsorption towers 200 in which desorption and adsorption are alternately performed; Nonwoven filters 300 and 300 'formed at the lower portions of the first bed 210 and the second bed 210', respectively; A fibrous activated carbon (400,400 ') formed on the nonwoven fabric filter (300,300') and arranged in a zigzag shape; Hot air supply pipe (500) formed on the upper side of the fibrous activated carbon (400, 400 ') for supplying hot air of 70 ~ 90 ℃; A suction pipe (600) formed under the fibrous activated carbon (400, 400 ') for sucking volatile organic compounds desorbed; An air supply damper (700,700 ') formed at a lower portion of the suction pipe (600) to open and close a lower space of the suction pipe (600); Exhaust dampers (710,710 ') formed on the hot air supply pipe (500) to open and close the upper space portion of the hot air supply pipe (500); Two-bed adsorption tower is embedded in the fibrous activated carbon, characterized in that it comprises a. The method of claim 1, A two-bed adsorption tower embedded with fibrous activated carbon, wherein the fibrous activated carbon (410, 410 ') is installed on the upper side of the staggered fibrous activated carbon (400,400'). The method of claim 1, In the first and second beds 210 and 210 ', two beds containing fibrous activated carbon (400, 400') are installed to indicate the replacement time of the fibrous activated carbon (400,400 ') periodically by installing differential pressure gauges (800,800'), respectively. Type adsorption tower (200). The method of claim 1, The nonwoven filter (300,300 ') is a two-bed adsorption column embedded with fibrous activated carbon, characterized in that it comprises a nonwoven filter (310,310') arranged in a horizontal manner and a nonwoven filter (320,320 ') arranged in a zigzag form.

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