KR102613321B1 - F0rmaldehyde absorbing apparatus of formalin manufacturing equipment - Google Patents

Abstract

The present invention relates to a formaldehyde gas absorption device for formalin manufacturing equipment, which includes a first absorption tower in which upper and lower structure packings are provided at vertical intervals; A second absorption tower located at a distance from the first absorption tower and having upper and lower structure packings spaced vertically therein and a plurality of bubble cap trays provided vertically above the upper structure packing; A gas connection pipe connecting the upper part of the first absorption tower and the lower part of the second absorption tower; a scrubber that purifies and discharges low-concentration formaldehyde gas that has passed through the second absorption tower; a first circulation flow unit that circulates a portion of the soft water that has passed through the upper structure packing of the second absorption tower so that it passes through the upper structure packing again; a second circulation flow unit that circulates a portion of the soft water that has passed through the lower structure packing of the second absorption tower so that it passes through the lower structure packing again; A soft water connection pipe connecting the second circulation flow unit and the upper and lower structure packings of the first absorption tower; a third circulation flow unit that connects the lower and upper parts of the first absorption tower to circulate the soft water in the lower part of the first absorption tower through the upper and lower structure packings; and a product dispensing unit connected to the third circulation flow unit to measure the concentration of soft water flowing through the third circulation flow unit and dispensing the product when the concentration exceeds a set concentration.

Description

Formaldehyde gas absorption device of formalin manufacturing equipment {F0RMALDEHYDE ABSORBING APPARATUS OF FORMALIN MANUFACTURING EQUIPMENT}

The present invention relates to a formaldehyde gas absorption device for formalin manufacturing equipment.

Formaldehyde (HCHO) is a flammable colorless gas with a irritating odor, and is mainly commercialized in the form of a 37% or more aqueous solution and sold under the name formalin. The melting point of pure formaldehyde gas is -118℃, and the specific gravity of liquefied gas is 0.815 at -20℃. It is soluble in water and ether, and the aqueous solution is colorless and transparent with a stifling, irritating odor.

Formaldehyde is widely used in various fields. For example, it is used to synthesize phenol resin, urea resin, melamine resin, etc. It is used in formal resin, polyhydric alcohols such as hexamine and pentaerythritol, pesticides, disinfectants and other preservatives, and organic It is used in the production of synthetic raw materials, vinylon, paraformaldehyde, etc.

As an example of a method for producing formaldehyde, formaldehyde is produced by mixing methanol, air, and water vapor and performing oxidation and dehydrogenation reactions using silver in the form of particles as a catalyst. Formaldehyde gas is dissolved and absorbed in soft water in an absorption tower where soft water flows to produce formalin in the form of an aqueous solution.

Conventionally, equipment that produces formalin by dissolving and absorbing formaldehyde gas in soft water does not allow formaldehyde gas to be dissolved and absorbed in soft water efficiently, which not only reduces formalin productivity but also increases the emission of formaldehyde gas, a harmful gas, into the atmosphere. There is a problem.

The purpose of the present invention is to provide a formaldehyde gas absorption device for formalin manufacturing equipment that maximizes the dissolution of formaldehyde gas in soft water and minimizes the emission of formaldehyde gas, a harmful gas, into the atmosphere.

In order to achieve the purpose of the present invention, upper and lower structure packings are provided inside at vertical intervals, and formaldehyde gas generated in the reactor is supplied to the bottom of the lower structure packing and flows through the upper and lower structure packings. A first absorption tower flowing upward of the upper structure packing; It is located at a distance from the first absorption tower, and upper and lower structure packings are provided at vertical intervals inside, and a plurality of bubble cap trays are provided vertically above the upper structure packing, and the bubble cap tray A second absorption tower in which soft water is supplied from the top of the fields and flows downward through bubble cap trays and upper and lower structure packing; The upper part of the first absorption tower is connected to the lower part of the second absorption tower so that the formaldehyde gas that has passed through the first absorption tower flows upward through the upper and lower structural packing and bubble cap trays of the second absorption tower. A gas connection pipe that flows into the tower; a scrubber that purifies and discharges low-concentration formaldehyde gas that has passed through the second absorption tower; a first circulation flow unit that circulates a portion of the soft water that has passed through the upper structure packing of the second absorption tower so that it passes through the upper structure packing again; a second circulation flow unit that circulates the soft water that has gone through the lower structure packing of the second absorption tower to go through the lower structure packing again; A soft water connection pipe connecting the second circulation flow unit and the upper and lower structure packing of the first absorption tower so that a portion of the soft water circulating in the second circulation flow unit flows downward through the lower structure packing of the first absorption tower; a third circulation flow unit that connects the lower and upper parts of the first absorption tower to circulate the soft water in the lower part of the first absorption tower through upper and lower structure packing; A formaldehyde gas absorption device for formalin manufacturing equipment is provided, including a product extraction unit connected to the third circulation flow unit to measure the concentration of soft water flowing through the third circulation flow unit and discharging the product when the concentration exceeds a set concentration.

The first absorption tower has a tower vessel with a set height and into which formaldehyde gas and soft water flow, respectively, and a lower structure installed on the inner lower side of the tower vessel to dissolve formaldehyde gas in soft water as formaldehyde gas and soft water intersect. It is preferable to include packing and an upper structure packing that is installed inside the top container above the lower structure packing and dissolves formaldehyde gas in the soft water as formaldehyde gas and soft water intersect.

The second absorption tower has a tower vessel with a set height and into which formaldehyde gas and soft water flow, respectively, and a lower structure installed on the inner lower side of the tower vessel to dissolve formaldehyde gas in soft water as formaldehyde gas and soft water intersect. Packing, an upper structure packing installed inside the top container to be located above the lower structure packing and dissolving formaldehyde gas in the soft water as formaldehyde gas and soft water intersect, and a tower to be located above the upper structure packing. It is preferable to include a plurality of bubble cap trays installed in the container, each allowing formaldehyde gas to pass through the soft water.

The first circulation flow unit is connected on one side to the absorption tower to be located between the upper and lower structure packing of the second absorption tower, and the other side is connected to the second absorption tower to be located above the upper structure packing of the second absorption tower. It is preferable to include a circulation connection pipe, a circulation pump connected to the circulation connection pipe to pump soft water, and a cooler connected to the circulation connection pipe to cool the soft water.

The second circulation flow unit is connected on one side to the second absorption tower so as to be located below the lower structure packing of the second absorption tower, and the other side is connected to the second absorption tower so as to be located between the upper and lower structure packing of the second absorption tower. It is preferable to include a circulation connection pipe connected to the circulation connection pipe, a circulation pump connected to the circulation connection pipe to pump soft water, and a cooler connected to the circulation connection pipe to cool the soft water.

The third circulation flow unit is connected on one side to the first absorption tower so as to be located below the lower structure packing of the first absorption tower, and the other side is connected to the first absorption tower so as to be located above the upper structure packing of the first absorption tower. It is preferable to include a circulation connection pipe connected to the circulation connection pipe, a circulation pump connected to the circulation connection pipe to pump soft water, and a cooler connected to the circulation connection pipe to cool the soft water.

In the present invention, the formaldehyde gas generated in the reactor goes through the upper and lower structure packing of the first absorption tower, then the upper and lower structure packing of the second absorption tower, and then flows to the scrubber through a plurality of bubble cap trays, and softens the water. As the soft water supplied from the tank passes through the upper and lower structure packing of the second absorption tower and a plurality of bubble cap trays, formaldehyde gas is dissolved in the soft water, and then the soft water flows into the first absorption tower, As formaldehyde gas is dissolved in soft water through lower structure packing, the dissolution of formaldehyde gas in soft water is maximized and the concentration of formaldehyde gas is minimized, which not only increases product productivity of formalin with formaldehyde gas dissolved in soft water. Minimize atmospheric emissions of formaldehyde gas, a harmful gas.

In addition, in the present invention, a portion of the soft water repeatedly passes through the upper structure packing of the second absorption tower by the first circulation flow unit, and the soft water repeatedly passes through the lower structure packing of the second absorption tower by the second circulation flow unit. Since the soft water repeatedly goes through the upper and lower structure packing of the first absorption tower by the third circulation flow unit, the absorption efficiency of formaldehyde gas dissolved in the soft water is further increased, thereby increasing the product productivity of formalin and eliminating formaldehyde, a harmful gas. It is environmentally friendly as it significantly reduces gas emissions into the atmosphere.

1 is a piping diagram showing an embodiment of the formaldehyde gas absorption device of the formalin manufacturing equipment according to the present invention;
Figure 2 is a front cross-sectional view of a plurality of bubble cap trays constituting an embodiment of the formaldehyde gas absorption device of the formalin manufacturing equipment according to the present invention.

Hereinafter, an embodiment of the formaldehyde gas absorption device of the formalin manufacturing equipment according to the present invention will be described with reference to the accompanying drawings.

Figure 1 is a piping diagram showing an embodiment of the formaldehyde gas absorption device of the formalin manufacturing equipment according to the present invention.

As shown in Figure 1, an embodiment of the formaldehyde gas absorption device of the formalin production equipment according to the present invention includes a first absorption tower 100, a second absorption tower 200, a gas connection pipe 10, It includes a scrubber 20, a first circulation flow unit 30, a second circulation flow unit 40, a soft water connection pipe 50, a third circulation flow unit 60, and a product extraction unit 70.

The first absorption tower 100 is provided with upper and lower structure packings 120 and 130 spaced apart in the vertical direction, and a reactor (not shown) is located below the lower structure packing 130. The formaldehyde gas generated in is supplied and flows upwards of the upper structure packing 120 through the upper and lower structure packings 120 and 130.

As an example of the first absorption tower 100, the first absorption tower 100 includes a tower container 110 having a set height, a lower structure packing 130 installed on the inner lower side of the tower container 110, and It includes an upper structure packing 120 installed inside the top container 110 so as to be located above the lower structure packing 130.

As an example of the top container 110, the top container 110 preferably has a set height and a uniform inner diameter. A gas inlet 111 through which formaldehyde gas generated in the reactor flows is provided at the bottom of the tower container 110, and a gas outlet 112 through which the gas connection pipe 10 is connected is provided at the top of the tower container 110. It is provided. A third circulation outlet 113 to which the third circulation flow unit 60 is connected is provided at the bottom of the top container 110, and the third circulation flow unit is installed in the top container 110 to be located above the upper structure packing 130. A third circulation inlet 114 to which (60) is connected is provided. A soft water inlet 115 is provided in the top container 110 to be located between the upper and lower structure packings 120 and 130.

The upper structure packing 120 and the lower structure packing 130 of the first absorption tower 100 pass soft water from top to bottom, and at the same time, gas passes from bottom to top, so that soft water and gas intersect, dissolving the gas in the soft water. This is a known technology.

The second absorption tower 200 is located at a distance from the first absorption tower 100, and is provided with upper and lower structure packings 220 and 230 at vertical intervals inside, and an upper structure packing 220 ), a plurality of bubble cap trays (T) are provided in a vertical direction, and soft water is supplied from above the bubble cap trays (T) to form the bubble cap trays (T) and the upper and lower structure packings (220). )(230) and flows downward.

As an example of the second absorption tower 200, the second absorption tower 200 includes a tower container 210 having a set height, a lower structure packing 230 installed on the inner lower side of the tower container 210, and An upper structure packing 220 installed inside the top container 210 to be located above the lower structure packing 230, and an upper structure packing 220 installed in the top container 210 to be located above the upper structure packing 220. Includes multiple bubble cap trays (T).

As an example of the top container 210, the top container 210 preferably has a set height and a uniform inner diameter. The inner diameter of the tower vessel 210 of the second absorption tower 200 is smaller and higher than the inner diameter of the tower vessel 110 of the first absorption tower 100. A gas inlet 211 through which a gas connection pipe 10 is connected is provided at the bottom of the top vessel 210 of the second absorption tower 200, and a soft water inlet 212 through which soft water flows into the upper part of the tower vessel 210. ) is provided. A first circulation outlet 213 through which the first circulation flow unit 30 is connected to the top container 210 is provided so as to be located between the upper and lower structure packings 220 and 230, and the upper structure packing 220 A first circulation inlet 214 to which the first circulation flow unit 30 is connected is provided to the tower container 210 so as to be located above. A second circulation outlet 215 is provided to which the second circulation flow unit 40 is connected to the top container 210 so as to be located below the lower structure packing 230, and the upper and lower structure packings 220 and 230 ) A second circulation inlet 216 to which the second circulation flow unit 40 is connected is provided to the tower vessel 210 so as to be located between the tower vessels 210 and the second circulation inlet 216.

The upper structure packing 220 and the lower structure packing 230 of the second absorption tower 200 pass soft water from top to bottom, and at the same time, gas passes from bottom to top, so that soft water and gas intersect, dissolving the gas in the soft water. This is a known technology.

As shown in FIG. 2, the bubble cap trays (T) include a plurality of bubble tab trays (240) installed at vertical intervals inside the top container (210). It is preferable that the bubble cap trays (T) have 5 to 10 bubble cap trays (240).

As an example of the bubble cap tray 240, the bubble cap tray 240 includes a base plate 241 that is coupled to be positioned horizontally inside the second absorption tower 200 and is provided with a plurality of coupling holes, and the base. A water level control plate 242 that is vertically coupled to one side of the plate 241 to form a tray filled with soft water inside along with the inner wall of the tower vessel 210 and the base plate 241, and the base plate 241. A gas fluid 243 that is penetrated through the coupling holes and allows gas to pass through, and a bubble cap that covers the top of the gas fluid 243 and allows the gas passing through the gas fluid 243 to pass through the soft water filled in the tray ( 244) and a fastening unit 245 that secures the bubble cap 244 to the gas fluid 243.

As an example of the gas fluid 243, the gas fluid 243 includes a cylindrical portion 1 having a uniform outer diameter and a set length, a covering plate portion 2 that covers the upper end of the cylindrical portion 1, and a cylindrical portion. It includes a plurality of gas discharge holes (3) formed at intervals in the circumferential direction on the upper outer peripheral surface of (1). The gas fluid 243 penetrates and is coupled to the coupling hole of the base plate 241 so as to protrude upward.

As an example of the bubble cap 244, the bubble cap 244 includes a cylindrical portion 4 having a uniform outer diameter and a set length, a covering plate portion 5 that covers the upper end of the cylindrical portion 4, and a cylindrical portion 4. It includes a plurality of gas discharge holes (6) formed at intervals in the circumferential direction at the lower part of (4). The inner diameter of the cylindrical portion 4 of the bubble cap 244 is formed to be larger than the outer diameter of the cylindrical portion 1 of the gas fluid 243. The gas discharge holes 6 of the bubble cap 244 are preferably formed in a line in the circumferential direction, and as another example, the gas discharge holes 6 may be formed in a zigzag shape. The bubble cap 244 covers the gas fluid 243 so that the gas fluid 243 is located inside, and the cover plate portion 5 of the bubble cap 244 and the cover plate portion 2 of the gas fluid 243 are connected as a fastening unit. Fasten with (245).

The water level filled in the tray formed by the inner wall of the tower vessel 210 of the second absorption tower 200 and the water level control plate 242 is higher than the height of the gas discharge hole 6 of the bubble cap 244 and the gas fluid 243 It is maintained in a range lower than the height of the gas discharge hole (3), and if it is higher than that range, the soft water flows beyond the water level control plate (242) and into the bubble cap tray (240) below.

Not only does it adjust the height of the bubble cap 244 between the cover plate part 2 of the gas fluid 243 and the cover plate part 5 of the bubble cap 244, but also the distance between the gas fluid 243 and the bubble cap 244. Additional spacers may be provided.

The bubble cap tray 240 allows gas to flow through the inside of each of the gas fluids 243 and flow into each bubble cap 244 through the gas discharge holes 3, and the gas flowing into each bubble cap 244 As it exits through the gas discharge holes 6 of the bubble cap 244, it passes through the soft water and flows to the bubble cap tray 240 above. As the gas passes through the soft water, the gas is dissolved in the soft water. In this way, as the soft water passes through the plurality of bubble cap trays (T), the gas is dissolved in the soft water, causing the concentration of the soft water to increase and the concentration of the gas to become very low.

A soft water supply pipe 81 connected to the soft water tank 80 is connected to the soft water inlet 212 of the second absorption tower 200, and a pumping unit 82 is connected to the soft water supply pipe 81. By pumping of the pumping unit 82, the soft water in the soft water tank 80 is supplied to the upper part of the second absorption tower 200 through the soft water supply pipe 81.

The gas connection pipe 10 connects the upper part of the first absorption tower 100 and the lower part of the second absorption tower 200 so that the formaldehyde gas that has passed through the first absorption tower 100 flows into the second absorption tower 200. It is introduced into the second absorption tower 200 to flow upward through the upper and lower structure packings 220 and 230 and the bubble cap trays (T). That is, one end of the gas connection pipe 10 is connected to the gas outlet 112 of the first absorption tower 100, and the other end is connected to the gas inlet 211 of the second absorption tower 200.

The scrubber 20 purifies the low-concentration formaldehyde gas that has passed through the second absorption tower 200 and discharges it into the atmosphere. An exhaust port 217 is provided at the top of the second absorption tower 200, one side of the exhaust connector is connected to the exhaust port 217, and a scrubber 20 is connected to the other side. Scrubber 20 is a known technology.

The first circulation flow unit 30 circulates a portion of the soft water that has passed through the upper structure packing 220 of the second absorption tower 200 so that it passes through the upper structure packing 220 again.

As an example of the first circulation flow unit 30, the first circulation flow unit 30 is located between the upper and lower structure packings 220 and 230 of the second absorption tower 200 (230). A circulation connection pipe 31 connected on one side to the second absorption tower 200 and the other end connected to the second absorption tower 200 so as to be located above the upper structure packing 220 of the second absorption tower 200, and the circulation connection pipe It includes a circulation pump (32) connected to (31) to pump soft water, and a cooler (33) connected to the circulation connection pipe (31) to cool the soft water. One end of the circulation connection pipe 31 is connected to the first circulation outlet 213 of the second absorption tower 200, and the other end is connected to the first circulation inlet 214.

In the first circulation flow unit 30, a portion of the soft water that has passed through the upper structure packing 220 is pumped by the operation of the circulation pump 32 and supplied to the upper part of the upper structure packing 220 through the circulation connection pipe 31. and goes through the upper structure packing (220) again.

The second circulation flow unit 40 circulates the soft water that has passed through the lower structure packing 230 of the second absorption tower 200 so that it passes through the lower structure packing 230 again.

As an example of the second circulation flow unit 40, one side of the second circulation flow unit 40 is connected to the second absorption tower 200 so as to be located below the lower structure packing 230 of the second absorption tower 200. A circulation connection pipe (41) whose other end is connected to the second absorption tower (200) so as to be located between the upper and lower structure packings (220) and (230) of the second absorption tower (200), and the circulation connection pipe It includes a circulation pump (42) connected to (41) to pump soft water, and a cooler (43) connected to the circulation connection pipe (41) to cool the soft water. One end of the circulation connection pipe 41 is connected to the second circulation outlet 215 of the second absorption tower 200, and the other end is connected to the second circulation inlet 216.

In the second circulation flow unit 40, soft water that has passed through the lower structure packing 230 is pumped by the operation of the circulation pump 42 and supplied to the upper part of the lower structure packing 230 through the circulation connection pipe 41. It goes through the lower structure packing (230).

The soft water connection pipe 50 allows a portion of the soft water circulating in the second circulation flow unit 40 to flow downward through the lower structure packing 130 of the first absorption tower 100. It is connected between the upper and lower structure packings 120 and 130 of the first absorption tower 100. That is, one end of the soft water connection pipe 50 is connected to the circulation connection pipe 41 of the second circulation flow unit 40, and is connected to be located between the cooler 43 and the second circulation inlet 216, and the other end is connected to the circulation connection pipe 41 of the second circulation flow unit 40. One end is connected to the soft water inlet 115 of the first absorption tower 100.

The third circulation flow unit 60 connects the lower and upper parts of the first absorption tower 100 to circulate the soft water in the lower part of the first absorption tower 100 through the upper and lower structure packings 120 and 130. Circulate it to do so.

As an example of the third circulation flow unit 60, the third circulation flow unit 60 is located on one side of the first absorption tower 100 so as to be located below the lower structure packing 130 of the first absorption tower 100. A circulation connection pipe 61 connected to the first absorption tower 100 on the other end to be located above the upper structure packing 120 of the first absorption tower 100, and connected to the circulation connection pipe 61. It includes a circulation pump 62 that pumps soft water, and a cooler 63 that is connected to the circulation connection pipe 61 to cool the soft water. That is, one end of the circulation connection pipe 61 is connected to the third circulation outlet 113 of the first absorption tower 100, and the other end is connected to the third circulation inlet 114.

In the third circulation flow unit 60, soft water that has passed through the lower structure packing 130 is pumped by the operation of the circulation pump 62 and supplied to the upper part of the upper structure packing 120 through the circulation connection pipe 61. It goes through upper structure packing (120) and lower structure packing (130).

The product dispensing unit 70 is connected to the third circulation flow unit 60, measures the concentration of soft water flowing through the third circulation flow unit 60, and dispenses it when the concentration exceeds the set concentration. The product extraction unit includes a branch pipe 71 connected to the third circulation flow unit 60, a product tank 72 connected to the branch pipe 71, and a third circulation flow unit adjacent to the branch pipe 72. It includes a concentration sensor 73 provided in the unit 60 and a valve unit 74 that controls soft water of the third circulation flow unit 60 to flow into the branch pipe 71.

Hereinafter, the operation and effect of the formaldehyde gas absorption device of the formalin manufacturing equipment according to the present invention will be described.

First, the formaldehyde gas generated in the reactor is continuously supplied to the lower part of the first absorption tower 100 through the gas inlet of the first absorption tower 100, and the formaldehyde gas is supplied to the lower part of the first absorption tower 100. The aldehyde gas flows to the top of the first absorption tower (100), passes through the lower structure packing (130) and the upper structure packing (120), and is then purified through the gas connection pipe (10) connected to the first absorption tower (100). 2 Formaldehyde gas flowing into the lower part of the absorption tower 200 and flowing into the lower part of the second absorption tower 200 flows to the upper part of the second absorption tower 200 and packs the lower structure of the second absorption tower 200. (230), the upper structure packing (220), a plurality of bubble cap trays (T), and then the exhaust connector connected to the upper part of the second absorption tower (200) and the scrubber (20) connected to the exhaust connector. It is then exhausted into the atmosphere.

At the same time, the soft water stored in the soft water tank 80 is continuously supplied to the upper part of the second absorption tower 200, and the soft water supplied to the upper part of the second absorption tower 200 is absorbed by the bubble cap trays (T ), the upper structure packing (220), and the lower structure packing (230) flow to the lower part of the second absorption tower (200), and as the soft water passes through the bubble cap trays (T), formaldehyde gas is dissolved in the soft water. The concentration of the soft water increases and the concentration of formaldehyde gas decreases. Then, as the soft water goes through the upper structure packing (220) and the lower structure packing (230), the formaldehyde gas is dissolved in the soft water, and the concentration of the soft water gradually increases and the gas concentration increases. concentration decreases. That is, the concentration of formaldehyde gas becomes very low as it passes through the lower structure packing 230, the upper structure packing 220, and the plurality of bubble cap trays (T).

At the same time, by the operation of the first circulation flow unit 30, a portion of the soft water that has passed through the upper structure packing 220 of the second absorption tower 200 is repeatedly passed through the upper structure packing 220, and the second circulation is performed. By operating the flow unit 40, the soft water that has passed through the lower structure packing 230 of the second absorption tower 200 is repeatedly passed through the lower structure packing 230 so that formaldehyde gas is dissolved as much as possible in the soft water. 2 A portion of the soft water circulating in the circulation flow unit 40 is supplied upward to the lower structure packing 130 of the first absorption tower 100 through the soft water connection pipe 50 and is supplied to the first absorption tower 100. The soft water flows to the lower part of the first absorption tower (100) through the lower structure packing (130), and by the operation of the third circulation flow unit (60), the soft water in the lower part of the first absorption tower (100) is absorbed into the first absorption tower (100). It is supplied above the upper structure packing 120 of the tower 100 and repeatedly passes through the upper structure packing 120 and the lower structure packing 130 of the first absorption tower 100 so that formaldehyde gas is dissolved as much as possible in the soft water. do. The concentration of the soft water circulating in the third circulation flow unit 60 is measured, and if the concentration of formaldehyde gas dissolved in the soft water is higher than the set concentration, it is taken out and stored in the product extraction unit 70.

As such, in the present invention, the formaldehyde gas generated in the reactor passes through the upper and lower structure packings 120 and 130 of the first absorption tower 100, and then the upper and lower structure packings of the second absorption tower 200 ( After passing through 220) (230), it flows to the scrubber 20 through a plurality of bubble cap trays (T), and the soft water supplied from the soft water tank 80 is packed in the upper and lower structures of the second absorption tower 200. Formaldehyde gas is dissolved in soft water while passing through (220) (230) and a plurality of bubble cap trays (T), and then the soft water flows into the first absorption tower (100), As formaldehyde gas is dissolved in soft water through the lower structure packing (120) (130), the dissolution of formaldehyde gas in soft water is maximized and the concentration of formaldehyde gas is minimized to form a formalin product in which formaldehyde gas is dissolved in soft water. Not only does it increase productivity, it also minimizes atmospheric emissions of formaldehyde gas, a harmful gas.

In addition, the present invention allows a portion of the soft water to repeatedly pass through the upper structure packing 220 of the second absorption tower 200 by the first circulation flow unit 30, and the softened water by the second circulation flow unit 40. After repeatedly passing through the lower structure packing 230 of the second absorption tower 200, the soft water is transferred to the upper and lower structure packings 120 and 130 of the first absorption tower 100 by the third circulation flow unit 60. As it goes through repeatedly, the absorption efficiency of formaldehyde gas dissolved in soft water is further increased, thereby increasing formalin product productivity and further minimizing the atmospheric emissions of formaldehyde gas, a harmful gas.

100; First absorption tower 200; 2nd absorption tower
10; gas connector 20; scrubber
30; First circulation flow unit 40; Second circulation flow unit
50; medulla oblongata 60; Third circulation flow unit
70; Product take-out unit

Claims (6)

The upper and lower structure packings are provided inside at vertical intervals, and formaldehyde gas generated in the reactor is supplied to the bottom of the lower structure packing and flows upwards of the upper structure packing through the upper and lower structure packings. 1 absorption tower;
It is located at a distance from the first absorption tower, and upper and lower structure packings are provided at vertical intervals inside, and a plurality of bubble cap trays are provided vertically above the upper structure packing, and the bubble cap tray A second absorption tower in which soft water is supplied from the upper part of the field and flows downward through the bubble cap trays and the upper and lower structure packings;
The upper part of the first absorption tower is connected to the lower part of the second absorption tower so that the formaldehyde gas that has passed through the first absorption tower flows upward through the upper and lower structural packing and bubble cap trays of the second absorption tower. A gas connection pipe that flows into the tower;
a scrubber that purifies and discharges low-concentration formaldehyde gas that has passed through the second absorption tower;
a first circulation flow unit that circulates a portion of the soft water that has passed through the upper structure packing of the second absorption tower so that it passes through the upper structure packing again;
a second circulation flow unit that circulates a portion of the soft water that has passed through the lower structure packing of the second absorption tower so that it passes through the lower structure packing again;
A soft water connector connecting the second circulation flow unit and the upper and lower structure packings of the first absorption tower so that a portion of the soft water circulating in the second circulation flow unit flows downward through the lower structure packing of the first absorption tower. ;
a third circulation flow unit that connects the lower and upper parts of the first absorption tower to circulate the soft water in the lower part of the first absorption tower through the upper and lower structure packings; and
It includes a product dispensing unit connected to the third circulation flow unit to measure the concentration of soft water flowing through the third circulation flow unit and dispensing the product when the concentration exceeds a set concentration,
The second absorption tower has a tower vessel with a set height and into which formaldehyde gas and soft water flow, respectively, and a lower structure installed on the inner lower side of the tower vessel to dissolve formaldehyde gas in soft water as formaldehyde gas and soft water intersect. Packing, an upper structure packing installed inside the top container to be located above the lower structure packing and dissolving formaldehyde gas in the soft water as formaldehyde gas and soft water intersect, and a tower to be located above the upper structure packing. It includes a plurality of bubble cap trays installed in the container, each allowing formaldehyde gas to pass through the soft water,
The bubble cap tray is coupled to the inside of the second absorption tower in a horizontal direction and has a base plate provided with a plurality of coupling holes, and is vertically coupled to one side of the base plate to connect the inner wall of the tower vessel and the base plate. A water level control plate that forms a tray filled with soft water inside, a gas fluid that is respectively penetrated into the coupling holes of the base plate and allows gas to pass through, and a gas that covers the top of the gas fluid and passes through the gas fluid. A formaldehyde gas absorption device for formalin manufacturing equipment including a bubble cap that allows soft water filled in a temporary tray to pass through, and a fastening unit that secures the bubble cap to the gas fluid. delete delete The method of claim 1, wherein the first circulation flow unit is connected on one side to the absorption tower so as to be located between the upper and lower structure packings of the second absorption tower, and is positioned above the upper structure packing of the second absorption tower. Absorbing formaldehyde gas in formalin manufacturing equipment that includes a circulation connection pipe connected to the tower on the other end, a circulation pump connected to the circulation connection pipe to pump soft water, and a cooler connected to the circulation connection pipe to cool the soft water. Device. The method of claim 1, wherein the second circulation flow unit is connected to the second absorption tower on one side so as to be located below the lower structure packing of the second absorption tower and is positioned between the upper and lower structure packings of the second absorption tower. 2 Formaldehyde of formalin manufacturing equipment including a circulation connection pipe connected to the absorption tower on the other end, a circulation pump connected to the circulation connection pipe to pump soft water, and a cooler connected to the circulation connection pipe to cool the softened water. Gas absorption device. The method of claim 1, wherein the third circulation flow unit is connected on one side to the first absorption tower so as to be located below the lower structure packing of the first absorption tower and is located above the upper structure packing of the first absorption tower. Formaldehyde gas of formalin manufacturing equipment including a circulation connection pipe connected to the absorption tower on the other end, a circulation pump connected to the circulation connection pipe to pump soft water, and a cooler connected to the circulation connection pipe to cool the soft water. Absorption device.

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