KR200490715Y1 - Dioxin abatement products using activated carbon and thermoplastic resin - Google Patents

Abstract

The present invention relates to a dioxin reduction product using activated carbon and a thermoplastic resin, and more particularly, activated carbon and a thermoplastic resin, characterized in that the dioxin generated during the process of steelmaking to industrial waste is formed of 10 to 22% activated carbon and a thermoplastic resin. It relates to the used dioxin reduction product.
Polling 80 filled in the washing tower 60 packed bed 61 of the present invention, the activated carbon of 10 to 22% by weight ratio; 78 to 90% by weight of the thermoplastic resin; characterized in that it is molded, including, to increase the surface area, at least one cylindrical cylinder (81); And at least one vertical wall (82, 83, 84) fastened to the inside of the cylinder (81). In addition, the folding is characterized in that it comprises at least one of a dehydration step, a drying step, a water separation step before binding to the thermoplastic resin, in order to increase the content of activated carbon.
Since the present design contains 10 to 22% of activated carbon by weight ratio, the dioxin adsorption capacity is very high, so the dioxin reduction effect is maintained continuously without changing the filler for more than one year. Dioxin abatement effects remain high.

Description

Dioxin abatement products using activated carbon and thermoplastic resin

The present invention relates to a dioxin-reducing product using activated carbon and a thermoplastic resin, and more particularly, activated carbon and a thermoplastic resin, characterized in that the dioxin generated in the process of steelmaking to industrial waste is formed of 10 to 22% activated carbon and a thermoplastic resin. It relates to the used dioxin reduction product.

Generally, incineration facilities, which are air pollution prevention facilities, contain harmful gases such as dust, sulfur dioxide, nitrogen oxides and dioxin when incineration of waste.

In order to remove the harmful gas, as shown in FIG. 1, an air pollution prevention facility including a reaction tower 30, a bag filter 40, and a washing tower 60 is provided.

It is composed of a first reduction step of spraying activated carbon in the bag filter 40 and a second reduction step of reducing dioxins with a filler in the form of a pall ring in the washing tower 60 as a method of reducing the dioxins. .

Since the air temperature flowing into the washing tower 60 is in a high temperature state of 80 to 100 ° C., thermoplastic resins are used a lot, and polypropylene (PP) materials are typically used.

The reason for using a lot of said thermoplastic resin is affinity with dioxins. That is, since the thermoplastic resin is composed of a carbon chain, since the dioxin molecules can easily penetrate, the affinity is very excellent.

However, the thermoplastic resin does not adsorb dioxins, but when the concentration of dioxins in the exhaust gas is relatively low, the absorbed dioxins are exhausted again to increase the dioxins concentration at the rear of the washing tower. memory effects often occur. This is because the thermoplastic resin is excellent in affinity with dioxins, but the bonding strength is not the main cause.

Therefore, the use of a thermoplastic resin having excellent affinity with dioxin, a situation that requires a technology capable of minimizing or reducing the memory effect by including a material having a high bonding strength with dioxin.

1. KR 10-0875519, 'Hazardous Substance Reduction Plant for Incinerator Flue Gas Using Activated Carbon', Registered Date: December 16, 2008. KR Special Publication 2003-0046982, 'Methods for Reducing Dioxin in Flue Gas Using Activated Carbon', Publication Date: 2003.06.18. 3. KR 10-0769667, 'Exhaust gas batch treatment system for incineration and combustion furnaces', date of registration: October 17, 2007. 4. KR 10-2007-0101182, 'Methods for Removing Nitrogen Oxides and Dioxins from Combustion Exhaust Gases Using Powder Impregnated Activated Carbon', Publication Date: October 16, 2007.

The present invention was devised to solve the above problems, and discloses a dioxin reduction product using activated carbon and a thermoplastic resin, characterized in that the thermoplastic resin is formed into a polling-type filler filled in a cleaning tower, including 10 to 22% of activated carbon. It is the purpose of the present invention.

In addition, another object of the present invention is to disclose a dioxin reduction product using activated carbon and a thermoplastic resin, characterized in that it comprises at least one cylindrical cylinder and at least one vertical wall fastened inside the cylinder. .

In order to achieve the above object, the present invention in the product to reduce harmful gases and dioxins in the air pollution prevention facility, the filler 80 is filled in the packed bed 61 of the washing tower 60, 10 by weight ratio 22% activated carbon; It is intended to disclose a dioxin-reducing product using activated carbon and a thermoplastic resin, characterized in that it comprises a thermoplastic resin of 78 to 90% by weight ratio.

In addition, the filler 80, at least one cylindrical cylinder (81) to increase the surface area; One or more vertical walls (82, 83, 84, 85) connected to the inner to the end portion of the cylinder 81; to disclose a dioxin reduction product using activated carbon and a thermoplastic resin.

In addition, the filler 80, in order to increase the content of activated carbon, before combining with the thermoplastic resin, the activated carbon and the thermoplastic resin, characterized in that it comprises at least one step of dehydration, drying, water separation process Disclosed is a dioxin reduction product used.

Due to the above solution, the present invention has the following effects.

First, by including activated carbon in the thermoplastic resin, the activated carbon adsorbs and combines the dioxin absorbed by the thermoplastic resin having excellent affinity with the dioxin, thereby significantly reducing the memory effect and excellent dioxin reduction effect.

Second, since it contains 10 to 22% of activated carbon by weight ratio, the dioxin adsorption capacity is very high, so the dioxin reduction effect is maintained without changing the filler for more than one year. The reduction effect remains high.

Third, the filler including at least one cylindrical cylinder and at least one vertical wall fastened inside the cylinder occupies a wide contact surface area with the washing water, thereby effectively removing acidic gas or dioxins in the exhaust gas.

1 is a flowchart of an air pollution prevention facility applied in an incinerator.
2 is a schematic diagram of an air pollution prevention facility applied in an incinerator.
3 is a perspective view (A) of the bag filter (40) and a dioxin adsorption conceptual diagram (B) using the spray activated carbon.
4 is a schematic diagram of the cleaning tower 60.
Figure 5 is a type of filler (A. B) of the polling form applied to the present invention.
Figure 6 is another polling type of filler (C, D) applied to the present invention.
7 is a condition and a test apparatus for comparing the performance of the conventional filler and the filler of the present invention.
8 is a graph of dioxins reduction of prior art fillers.
9 is a graph showing dioxins reduction when the filler of the present invention is used.
10 is a view of the first product (left) and the product (right) using the filler of the present invention (left) for 9 months.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and the same reference numerals are attached to the same or similar elements throughout the specification.

In addition, since the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, the present invention is not necessarily limited to those shown in the drawings. In the drawings, the thickness of layers, films, panels, regions, etc., are exaggerated for clarity.

The present invention relates to a dioxin-reducing product using activated carbon and a thermoplastic resin, and more particularly, activated carbon and a thermoplastic resin, characterized in that the dioxin generated in the process of steelmaking to industrial waste is formed of 10 to 22% activated carbon and a thermoplastic resin. It relates to the used dioxin reduction product.

The memory effect refers to a phenomenon in which dioxin concentration increases in the scrubbing tower 60. In other words, it refers to an abnormal phenomenon in which the concentration of the outlet is higher than that of the dioxin at the inlet of the washing tower 60.

The typical material of the thermoplastic resin is polypropylene (PP), which has a high affinity for dioxins. In the conventional general dioxin removal principle, dioxin is mainly absorbed and removed. Dioxins and P.P, however, apply the principle of absorption rather than adsorption.

Since PP is made of carbon chain, dioxin molecules can easily penetrate. Easily penetrated but easily vented, the lower the dioxin concentration in the exhaust gas, the dioxin absorbed by the PP is exhausted, the memory effect occurs.

In order to solve the above problems, the present invention is to disclose a filler formed by mixing activated carbon and a thermoplastic resin.

The present invention has the effect that the dioxin is absorbed through the thermoplastic resin, the absorbed dioxin is strongly adsorbed by the activated carbon is not exhausted to the outside. In other words, the dioxin of the exhaust gas is adsorbed on the activated carbon and binds very strongly with the carbon particles, thereby acting as a filter for harmful substances such as dioxin. Due to the very high binding force with carbon, dioxin tends not to be grown again, thereby reducing the dioxin concentration of the flue gas and minimizing the memory effect.

1 is a flowchart of an air pollution prevention facility applied in an incinerator, and FIG. 2 is a schematic view of an air pollution prevention facility applied in an incinerator.

The air pollution prevention facility includes a combustion furnace (10) for burning and burning wastes; A boiler (20) for driving a steam turbine by using heat generated by the combustion furnace (10); A reaction tower 30 by supplying slaked lime to the exhaust gas passed through the boiler; A bag filter for removing acid gas and dioxins after the reaction tower; A blower (50) for transferring the filter dust collector to a washing tower; A washing tower 60 for removing the remaining harmful gas and dust just before discharge into the atmosphere; The stack 70 is included.

The combustion furnace 10 is to incinerate workplace waste which is an incineration object, and all facilities currently used in an incineration facility can be used. Combustion furnace (10) is a waste to put the auxiliary air for combustion when burning in the grate to ensure complete combustion smoothly, by installing a diesel burner separately to reburn the incomplete combustion gas to achieve a complete combustion have.

The reaction tower 30 includes a SNCR for removing nitrogen oxide contained in exhaust gas, a cooling unit for cooling the exhaust gas, and a centrifugal separator for removing dust from harmful substances by centrifugal force.

The filter dust collector 40 is a semi-dry cleaning unit for removing acidic gas from harmful substances and adsorbing gaseous dioxins, a dry hazardous substance removing unit for removing dioxins, heavy metals and acid gases by powder activated carbon and powdered lime, and dust among harmful substances. And a dust filtration unit for adsorption and removal thereof.

3 is a perspective view (A) of the bag filter 40 and a conceptual diagram (B) of dioxin adsorption using sprayed activated carbon.

Among the methods for removing dioxin, a removal method by adsorption is commonly used. As shown in FIG. 3B, the adsorption method can simultaneously remove dioxins and the undissolved sulfur oxides of the sprayed water. The sorbent adsorbed by dioxins is collected at the rear end using a filter cloth or an electrostatic precipitator.

The adsorption method has the disadvantage of causing a fire if the exhaust gas contains a burnout or a relatively high temperature, and it is expensive to spray a constant amount of adsorbent at all times regardless of the concentration of dioxins in the exhaust gas. There was a disadvantage that untreated gas can pass to the blind area where turbulence is formed or the adsorbent does not reach, but it is used a lot because of the high dioxin reduction efficiency.

4 is a schematic diagram of the cleaning tower 60.

The washing tower 60 removes harmful substances not removed from the filter collector 40 using caustic soda, activated carbon powder and washing water, and supplies 33% or 50% caustic soda (NaOH) supply unit and washing water. Water tank, a tower through which exhaust gas passes, injection means 62 for removing harmful substances by injecting the washing water stored in the water tank into the internal exhaust gas, and expanding the contact area between the exhaust gas and the washing water. And a filling layer 61 for increasing the removal rate of the material.

The filling layer 61 may be mounted in multiple stages inside the tower, and may also be easily replaceable since harmful substances may be fixed.

A plurality of fillers are stacked in the filler layer 61, and the filler is preferably configured in the form of a falling ring in a structure having a large surface area and a structure in which exhaust gas can easily flow.

5 is a type of filling material (A. B) of the polling type applied to the present invention, Figure 6 is another type of filling material (C, D) of the polling type applied to the present invention.

Folding type filling material of the present invention, the polling 80, in order to increase the surface area, at least one cylindrical cylinder (81); At least one vertical wall (82, 83, 84, 85) connected to the inner to the end portion of the cylinder 81; characterized in that it comprises a.

The cylindrical cylinder 81 has a cylindrical shape, the width may vary depending on the use conditions. In addition, wrinkles or grooves may be formed on the outer circumferential surface to increase the surface area.

The vertical walls 82, 83, 84, and 85 include inclined walls 85 that are inclined at a predetermined angle to a vertical wall.

In addition, the vertical wall may be utilized in the form of a wired vertical wall 84 combined with a radial structure of the radial vertical wall 82 formed in a radial form with respect to the central axis to a streamlined vertical wall based on the central axis.

In addition, the vertical wall and the inclined wall 85 formed at regular intervals; It also includes a form (Fig. 6D); connecting the horizontal bar 86 for connecting the inclined wall (85).

The filler 80 may be formed with a vertical wall inside the cylindrical cylinder 81, or may be formed in a laminated structure in which the vertical wall is connected to the end of the cylinder 81 and the cylinder is connected again.

7 is a condition and a test apparatus for comparing the performance of the conventional filler and the filler of the present invention.

The test apparatus is inserted into the filler material of the existing PP material and the filler material of the present invention in the inner diameter 40cm, 3.5m length, respectively, and then mixed with air and dioxin dioxin concentration 5ngTEQ / Sm ³ , flow rate 1.7m / s, It was tested under the condition of an inlet temperature of 80 ° C.

As a result of applying for one month to the test apparatus, the existing PP filler was detected dioxin at the end, and when the inlet temperature was increased to 120 degrees, the dioxin concentration increased rapidly.

On the other hand, the filler of the present invention, that is, a filler molded from 10 to 22% activated carbon and a thermoplastic resin, did not detect dioxin and did not detect dioxin even when the inflow temperature was changed.

As a result of disassembling the filler of the present invention and examining how much dioxin is detected, dioxin was detected only at the first stage of the inlet.

The reason why the filler 80 according to the present invention has a high dioxin reduction effect is that the activated carbon adsorbs the thermoplastic resin excellent in the affinity of dioxins and the dioxins absorbed by the thermoplastic resin.

Therefore, the disadvantage of the existing product, that is, the memory effect is greatly improved, and the product of the present invention has been tested for more than nine months until now, it has been confirmed that there is little memory effect.

8 is a graph of dioxins reduction of the prior art filler, Figure 9 is a graph of dioxins reduction when the filler of the present invention is used.

The amount of dioxin absorbed by the filler depends on the chemical equilibrium of P.P and dioxin and is determined by factors such as dioxin concentration in the flue gas, contact time and temperature.

When the filler packed in the scrubber reaches equilibrium with dioxins in the gas, if the dioxin concentration in the gas increases, the dioxin concentration of the filler also increases, and the dioxin concentration of the filler decreases when the dioxin concentration in the gas decreases. However, while the concentration of dioxins in gas changes from time to time, the concentration of dioxins in fillers changes very slowly. As a result, the concentration of dioxins at the exit side may be higher than that of the dioxins at the inlet of the scrubber. This is called the memory effect.

8 and 9 when the dioxin concentration at the inlet of the washing tower is changed to 0.1ngTEQ / Sm ³ while supplying 5ngTEQ / Sm ³ , FIG. 8 is a dioxin reduction rate of the conventional filler and FIG. 9 is a dioxin reduction rate of the present filler. It is shown.

Although the concentration of dioxin supplied is lowered from ⁵ ngTEQ / Sm ³ to 0.1 ngTEQ / Sm ³ , as shown in FIG. 8, the existing filler is discharged at a higher concentration because dioxin absorbed in the PP material is discharged into the gas. do. In this case, it can be confirmed that equilibrium is reached only after several months (2 to 4 months).

As shown in Figure 9, the filling material of the subject innovation, that is, 10-22% of a filler formed in the activated carbon and the thermoplastic resin while the dioxins to be supplied to the washing column supplied to 5ngTEQ / Sm ^3, if changed to the O.1ngTEQ / Sm ³ When the memory effect does not occur at all, it was confirmed that the equilibrium was maintained within a short time.

Occasionally, the concentration of dioxin may increase rapidly due to the change of operating temperature of the scrubber tower.If this condition is simulated and supplied at a rate of 100ngTEQ / Sm ³ temporarily, and then supplied at 0.1ngTEQ / Sm ³ immediately. Was tested.

As a result of the test, the existing filler can be confirmed that the dioxin emission concentration is maintained for several months due to the memory effect, while the filler of the present invention is in equilibrium after 10 days.

10 is a view of the first product (left) and the product (right) using the filler of the present invention (left) for 9 months.

The product of the present invention has been developed and used in incineration air pollution prevention facilities for more than 10 months. As shown in FIG. 10, the product of the present invention was used for 9 months, but dust was partially adhered to the appearance, but the dioxin reduction effect was continuously maintained.

Korean Patent Application Publication No. KR 10-2007-0101182 discloses a method for removing nitrogen oxide and dioxins from combustion exhaust gas using powder-type impregnated activated carbon. The above technique discloses a dioxin abatement method using powdered impregnated activated carbon, but is inferior to the present invention because of the following reasons.

When using the powdered activated carbon with the washing water, the service life was very short. This is because activated carbon adsorbs dust, heavy metals, oils, and other VOCs together. These materials are much larger than dioxins and block the pores of activated carbon, preventing activated carbon from serving as a sufficient dioxin remover.

However, the filler of the present invention can prevent the adsorption of unwanted materials because the activated carbon inside is protected by a thermoplastic resin. Therefore, the filler of the present invention has a very large capacity for adsorption of dioxins.

The filler of the present invention is molded based on a thermoplastic resin, and it is very difficult to know the dioxin saturation concentration in a laboratory. A long time series of experiments is needed to know the dioxin saturation concentration of the present invention, but the result of one year of testing has not yet found a saturated result.

It is generally said that activated carbon can adsorb 30w% of dioxins. Therefore, it is estimated that the filling material of the present invention is difficult to saturate for several years by ng dioxins.

Filler 80 of the present invention, 10 to 22% by weight of activated carbon; 78 to 90% by weight of the thermoplastic resin; characterized in that the molded.

In addition, the filler 80 of the present invention, in order to increase the content of activated carbon, is characterized in that it comprises one or more steps of dehydration step, drying step, water separation step before bonding with the thermoplastic resin.

As shown in FIGS. 8 and 9, it was confirmed that the inclusion of activated carbon in the thermoplastic resin showed excellent performance. However, there are many difficulties in increasing the ratio of activated carbon in the thermoplastic resin.

When the activated carbon is mixed with the thermoplastic resin, only 5% of the weight ratio is possible.

Accordingly, the present applicant has confirmed that, through a number of studies and trials and errors, lowering the moisture content of activated carbon can increase the mixing ratio of activated carbon.

In order to reduce the water content of the activated carbon, the present invention is characterized by including one or more steps of a dehydration step, a drying step, and a water separation step.

In addition, the present invention comprises the steps of lowering the activated carbon moisture content in at least one of the process of dehydration, drying, water separation process to the activated carbon; Immediately after the step, 10 to 22% by weight of activated carbon; Mixing 78 to 90% by weight of the thermoplastic resin; Molding the mixture into a rod shape; It characterized in that it comprises the step of injecting a molded rod shape into the injection machine.

The reason for limiting the activated carbon ratio to 10 to 22% in the present invention is as follows.

If the ratio of activated carbon is less than 10%, a memory effect occurs and a disadvantage of lowering dioxin reduction efficiency occurs.

And when the activated carbon exceeds 22% there is a disadvantage that the folding-type filler is not easily injection molding.

In addition, even if the water content of the activated carbon is lowered, the activated carbon cannot be mixed with the thermoplastic resin by more than 22%.

As a result of the above, the present invention has the following effects.

First, by including activated carbon in the thermoplastic resin, the activated carbon adsorbs and combines the dioxin absorbed by the thermoplastic resin having excellent affinity with the dioxin, thereby significantly reducing the memory effect and excellent dioxin reduction effect.

Second, since it contains 10 to 22% of activated carbon by weight ratio, the dioxin adsorption capacity is very high, so the dioxin reduction effect is maintained without changing the filler for more than one year. The reduction effect remains high.

Third, the filler including at least one cylindrical cylinder and at least one vertical wall fastened inside the cylinder occupies a wide contact surface area with the washing water, thereby effectively removing acidic gas or dioxins in the exhaust gas.

10: combustion furnace, 20: boiler, 30: reaction tower,
40: bag filter, 50: blower, 60: washing tower,
61: packed bed, 62: spray means, 70: stack,
80: filling material, 81: cylinder, 82: radial vertical wall,
83: vertical bar, 84: wired vertical wall, 85: inclined wall,
86: Connecting horizontal bar.

Claims (4)

A combustion furnace 10 for combusting, a boiler 20 for driving a steam turbine with heat generated from the combustion furnace, a reaction tower 30 for lowering the temperature of exhaust gas exhausted from the boiler 20, and the reaction A filter dust collector 40 for reducing harmful exhaust gas by spraying powder slaked lime and activated carbon after the tower 30, a blower 50 for transporting exhaust gas to the cleaning tower after the filter dust collector, and exhaust exhausted by the blower In the product for reducing the harmful gas and dioxin applied to the air pollution prevention facility, including a washing tower 60 for reducing the gas secondary, and the stack 70 to exhaust to the atmosphere after the washing tower,
Filler 80 is filled in the packed layer 61 of the cleaning tower 60,
In order to increase the content of activated carbon, at least one of a dehydration step, a drying step, and a water separation step is included before bonding with the thermoplastic resin,
10 to 22% by weight of activated carbon;
78 to 90% by weight of the thermoplastic resin; Dioxin reduction product using the activated carbon and the thermoplastic resin, characterized in that it comprises a molded.
According to claim 1,
The filler 80 is,
At least one cylindrical cylinder 81 to increase the surface area;
At least one vertical wall (82, 83, 84, 85) connected to the inner end portion of the cylinder (81); Dioxin reduction product using the activated carbon and a thermoplastic resin. Lowering the activated carbon moisture content in at least one of the activated carbon dehydration process, drying process, and water separation process;
Immediately after the step, 10 to 22% by weight of activated carbon; Mixing 78 to 90% by weight of the thermoplastic resin;
Molding the mixture into a rod shape;
Injecting the formed rod shape into an injection machine; Dioxin reduction product using the activated carbon and a thermoplastic resin comprising a. delete

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