KR950011089B1 - Deodorization method and apparatus of exhust gas - Google Patents

Abstract

The method comprises (A) introducing odorous gas upwardly, while supplying wash water downwardly ; (B) neutralizing basic component of the gas in the neutralizing reactor (5) ; (C) decomposing remaining odorous component with bacteria in the baterial reaction bed (4) ; (D) discharging deodorized gas after adsorbing with wash water ; and (E) separating bacteria from wash water coming out of the bacterial reaction bed and the neutralization bed using a filter (2) equipped with ultrafiltration membrane, while recycling the wash water into the bacterial reaction bed with fresh water.

Description

Deodorization Exhaust Gas Deodorization Method and Device

1 is a schematic diagram of a deodorizing device of odor gas provided with a filtration device according to the present invention,

2 is a schematic diagram of an apparatus for deodorizing malodorous gas conventionally used.

* Explanation of symbols for main parts of the drawings

1, 21: deodorization tower 2: filtration device

3: water tank 4: microbial reaction layer

5: neutralization layer 6: nozzle

7, 9: outlet 8: inlet conduit

10: discharge pipe 11, 12: piping

22: filling layer 23: conduit

24: spray nozzle plate 25, 27: discharge conduit

26: washing water tank 28: reflux conduit

The present invention relates to a method and apparatus for deodorizing odorous exhaust gas. In particular, the present invention relates to a biological treatment method for neutralizing odorous exhaust gas generated in the fields of livestock agriculture, feed and fertilizer manufacturing plants, chemical plants, and sewage treatment plants with microorganisms and neutralization reactions. The present invention relates to a method for deodorizing treatment by combining physicochemical treatment by chemical liquid cleaning and a device used therein.

As a method of removing odor components included in gas phase liquors, such as hydrogen sulfide (H ₂ S), methyl disulfide (CH ₃ S ₂ ), methyl mercaptan (CH ₃ SH), ammonia (NH ₃ ), and the like, There are physicochemical methods such as combustion, chemical cleaning, adsorption, and biological methods such as soil deodorization and activated sludge, but these days require less treatment area, easier maintenance, no secondary pollution, and no gas treatment cost. This inexpensive biological treatment is drawing attention.

Japanese Patent Laid-Open No. 3-245815 discloses a method and apparatus for deodorizing by installing a plurality of carriers of a ceramic porous body in order to fix odor gas with microorganisms.

That is, the biological treatment method will be described based on FIG. 2 of the accompanying drawings. In the inner center of the biological deodorization tower 21, the filling layer 22 is fixed to the microorganism, and the lower left side of the filling layer 22 is provided with a conduit 23 through which odor gas is introduced. On top of the filling layer 22, a spray nozzle plate 24 for spraying water toward the filling layer 22 is provided. Therefore, when the odor gas is introduced into the biological deodorizing tower 21 through the conduit 23, it is oxidatively decomposed in contact with the microorganisms attached to the surface in the process of passing through the filling layer 22. However, since the product (sulfuric acid compound, nitrate compound) generated as a result of this decomposition is laminated on the packing layer 22 to gradually reduce the reaction activity of the microorganisms, the water injection nozzle plate 24 is regularly used to fill the top of the packing layer 22. Water is sprayed onto the product to clean the products stacked on the surface of the filling layer 22, and at the same time, water required for the growth of microorganisms is supplied.

On the other hand, the washing water passing through the filling layer 22 is stored in the washing tank 26 is stored. At this time, if the washing water is reused as it is, since the activity of microorganisms is reduced, alkali is supplied to the washing water tank 26 at regular intervals to increase the lowered pH (pH 6-8) to neutralize the washing water, and to wash a certain amount of water. While the water is discharged through the discharge conduit 27, the fresh water is supplied to the washing tank 26 again. The fresh bow neutralized with alkali through the reflux conduit 28 is then re-supplied to the water spray nozzle tube 24.

In FIG. 2, reference numeral 25 denotes an exhaust conduit of the treatment gas.

However, the problem with the conventional biological treatment method is as follows. That is, when it is necessary to remove a large amount of malodorous components, when the concentration of malodorous components is high, it is difficult to remove the malodorous components at a high concentration because the activity of the microorganisms is high, and when the concentration of malodorous components is large, the removal rate of malodorous components is large. Is very volatile.

On the other hand, Japanese Patent Application Laid-Open No. 1-315314 describes a method and apparatus for deodorizing by installing a microbial reaction tank and a neutralization tank as a packed bed in a deodorizing tower, but the higher the concentration of microorganisms in the packed bed, the better the deodorization removal rate is. ), Since not only products (sulfuric acid compounds and nitrate compounds) but also microorganisms are released from the packing layer, it is difficult to fix a large amount of microorganisms in the packing layer and the concentration distribution of the microorganisms in the packing layer becomes uneven by washing. That is, there is a problem that the amount of microorganisms present in the upper portion is lower than the lower portion of the filling layer.

Therefore, the present invention is to install a microbial reaction tank and a neutralization reaction tank in the deodorization tower to solve the above-mentioned conventional problems, microorganisms alternately separated through the two or more filtration apparatus washed down by the wash water being sprayed in the microbial reaction tank microorganisms It is an object of the present invention to provide a odor gas deodorization method and a device used therein, which can maintain a constant microbial concentration at all times by supplying the reaction tank so that a constant deodorization performance and deterioration of the deodorization removal rate even after long-term use are not caused.

Hereinafter, the present invention will be described in detail.

The present invention is a microbial reaction layer and odor component in which a nozzle for spraying down the water is sprayed between the inlet conduit into which the gas containing the odor component is introduced and the outlet through which the deodorized gas is discharged, and the microorganisms decomposing the odor component are fixed. In the deodorizing device of the odor gas is provided with a deodorization tower is provided with a neutralization reaction layer for neutralizing the basic components, the dewatering tower for discharging the washing water passing through the reaction layer, and the water tank for storing the washing water, It is characterized in that it is a deodorization device of odor gas by installing a filtration device connected in parallel with two filters incorporating a ceramic ultrafiltration membrane in the outlet and the low water irradiation.

In addition, the present invention is to supply the odor gas up, down supplying the washing water, neutralize the basic components of the odor components in the neutralization reaction layer, and then adsorb the remaining odor components in the microbial reaction layer to the microorganisms, and absorbed in the washing water After deodorizing, the deodorized gas is discharged, and the washing water passing through the microbial reaction layer and the neutralization reaction layer is stored and recycled together with a new athlete. The deodorizing method of odor gas which is passed through the washing water is separated by microorganisms using a filtration device in which a ceramic ultrafiltration membrane is embedded and then recycled to the microbial reaction layer together with the washing water.

When described in more detail based on the accompanying drawings of the present invention as follows.

The present invention relates to a method for deodorizing a malodorous gas and a device for use therein, as in a conventional apparatus for deodorizing malodorous gas, a malodorous component by neutralization reaction with a microbial reaction layer which decomposes the deodorizing component with microorganisms in a deodorizing tower. It is composed of a neutralization layer that deodorizes, and additionally, deodorization using two or more filtration devices for filtering and resupplying microorganisms washed off by washing water sprayed from the top of the microbial reaction layer to the microbial reaction layer. Device.

As a result, the concentration of the microorganisms in the microbial reaction layer is always kept constant, thereby reducing the deodorization performance (deodorization removal rate) even when operating for a long time.

1 is a diagram schematically illustrating a deodorizing device of a malodorous component used in the present invention, which includes a deodorization tower 1 for removing malodorous components, a filtration device 2 for filtration and separating microorganisms, and a storage water for It consists of a reservoir (3).

The deodorization tower 1 is provided with a microbial reaction layer 4 and a neutralization reaction layer 5 as a packing layer at the central portion thereof, and a nozzle 6 for spraying water on the microbial reaction layer 4. And the outlet 7 of the deodorized gas are respectively provided, and the inlet conduit 8 and the washing water outlet 9 through which the malodorous component flows are provided below the neutralization reaction layer 5, respectively.

The microbial reaction layer (4) is a packing layer for decomposing deodorizing components into microorganisms. As a typical filling material, an alumina material having a size of about 1 to 2 cm and an average pore size of 7 μm is used. Ceramic, polymer, fiber, activated carbon, etc. may be used, and the shape may be a lattice, a saddle, a column, or the like.

On the other hand, the microorganism can be used by immobilizing thiobacillus, vegeta, thiotrix, etc. in the packing layer as a nutrient source, methyl sulfide, methyl disulfide, methyl hydrogen sulfide and the like.

The neutralization reaction layer (5) is a packing layer for deodorizing basic ammonia and the like among the odorous components by a neutralization reaction, which is a physicochemical method, and a specific surface area of 260 m ² / m ² as a filler to increase the gas-liquid contact area. As mentioned above, it is preferable to use the thing of the saddle shape of the ceramic material more than 77% of space rate.

The filtration device 2 for separating the microorganisms contained in the washing water discharged through the deodorization tower 1 configured as described above is installed in front of the reservoir (3). The filtration device 2 includes a ceramic-based ultrafiltration membrane filter, and a first filter 2a and a second filter 2b are connected in parallel to alternately operate filtration and suppression at regular intervals.

On the other hand, the reservoir (3) is a place where the washing water passed through the filtration device (2) is stored, in order to adjust the lowered pH is automatically detected by the pH sensor to supply a certain amount of alkali (NaOH), some storage The water is discharged to the outside through the discharge pipe 10, on the other hand, the new player is automatically supplied.

Referring to the deodorizing process of the malodorous gas through the deodorizing device of malodorous gas according to the present invention having such a configuration as follows.

First, the malodorous gas is introduced into the deodorizing tower 1 through the inlet conduit 8. The inlet odor gas by first neutralizing the reaction layer 5 is a neutralization reaction layer 5, the cleaning liquid containing the product (such as H ₂ SO ₄₎ Falling acid through the storage contact neutralization reaction while passing through of the malodor components The components of the alkaline system (ammonia, etc.) are removed.

The neutralization reaction of malodorous gas occurring in this process is as follows.

Y ₁ = Ka × t × (XX ^m ) × P

Where Y ₁ is the reaction rate, Ka is the rate constant (Kg · mol / m ² / hr / atm), A is the gas-liquid contact area, X is the mole fraction of malodorous components in the gas, and X ^m Is the mole fraction of the malodorous component in the liquid, and P is the voltage atm.

Since there is almost no odor component in the liquid in the neutralization reaction formula, assuming that X ^m = ψ, the larger the gas-liquid contact area and the larger the mole fraction of the odor component in the gas, the higher the reaction rate. Therefore, when the alkali molar fraction of the odorous components introduced or the variation is large, the alkaline component is almost removed from the neutralization reaction layer 5 by the neutralization reaction.

The remaining malodorous gas passing through the neutralization reaction layer (5) is introduced into the microbial reaction layer (4) and is contacted with water sprayed from the spray nozzle (6) and absorbed by water, and the absorbed malodorous component is adsorbed by the microorganisms, Adsorbed malodorous components are used for the growth of energy sources of microorganisms and are produced as products such as sulfur compounds.

This process is described as a reaction equation as follows.

H ₂ S → H ₂ SO ₄ + S

CH ₃ SH → H ₂ SO ₄ + H ₂ O + CO ₂

(CH ₃ ) ₂ S → H ₂ SO ₄ + H ₂ O + CO ₂

NH ₃ → HNO ₂ + H ₂ O

Here, since the sulfur compound and nitric acid are fixed and laminated in the microbial reaction layer, the microbial activity is lowered. Therefore, the sulfur compound and the nitric acid need to be supplied with water for cleaning and stacking the microorganism. Therefore, the water is supplied to the water / gas (L / G) of about 1 to 1.5kg / cm ³ through the injection nozzle (6).

Then, the washing water supplied to the microbial reaction layer (4) is separated to the neutralization reaction layer (5) to neutralize the alkali salt in the odor component to remove the alkali salt.

On the other hand, since the washing water passing through the outlet 9 of the deodorizing tower 1 contains microorganisms separated from the microbial reaction layer 4, the first filter 2a of the filtration device 2 to separate them. Will pass through. That is, when the washing water flows into the first filter 2a in which the ceramic ultrafiltration membrane is embedded through the valve V1, microorganisms and filtrates are separated at the portions 2a 'and 2a ", respectively, and the filtrate is the valve V2. And flows into the reservoir 3 through the pipe 11. At this time, the valve V3 and the valve V4 are locked.

On the other hand, while the first filter 2a of the filtration device 2 operates, the second filter 2b operates to re-introduce microorganisms attached to the filtration membrane into the microbial reaction layer 4. That is, the second filter 2a is a cleaning solution having a pH of about 6 to 8 in the water storage tank 3, and sprays microorganisms and the cleaning solution through the valve V5 while suppressing the operation through the pipe 12 and the valve V7. It is supplied to the nozzle 6, and the supplied washing liquid is sprayed into the microbial reaction layer 4 of the deodorization tower 1.

At this time, the valve V6 and the valve V8 are locked.

The first filter 2a and the second filter 2b of the filtration device 2 operate while automatically switching the filtration operation and the depressing operation at intervals of about 20 to 30 minutes.

The reservoir 3 is configured to detect the cleaning liquid with a pH sensor in order to adjust the pH of the cleaning liquid to about 6 to 8, and alkali can be automatically introduced. Then, a certain amount of washing water is discharged to the outside through the discharge pipe 10, while a new player is replenished to the reservoir (3).

The gas deodorized in the process is discharged to the atmosphere through the outlet (7).

As such, the washing water passing through the deodorization tower is passed through the filtration apparatus, and the microorganisms in the upper and lower portions of the microbial reaction layer can be uniformly distributed by recycling the filtered microorganisms to the microbial reaction layer, thereby deodorizing the odor gas. In addition to increasing the function, it is possible to prevent deterioration of deodorization performance with time.

The present invention will be described in more detail with reference to the following Examples.

Example 1

Next, the odor gas containing the low concentration components as shown in Table 1, a microbial reaction tank made of alumina material, a porous body of 7 cm in size and having a pore size of 7 μm, and a specific surface area of 260 m ² / m ² , It consists of a neutralization layer made of a ceramic material on a saddle with a 77% rate and two filters with a 20 minute conversion time with a ceramic filter with a pore size of 0.1 μm. The odor gas throughput is 1 m ³ / sec. And deodorized by introducing into a deodorizing apparatus of the present invention having a space velocity of 8 m / sec.

After deodorizing in the apparatus, the result of measuring the concentration of the malodorous component in the exhaust gas (deodorizing performance) is shown in Table 1 below.

Comparative Example 1

The malodorous gas containing a low concentration of the same components as in Example 1, the microorganism filling layer is provided with a microorganism having a deodorizing action to the inorganic basic material of the blast furnace ceramics, the throughput of the malodorous gas is 1m ³ / second The deodorizing apparatus was introduced into a deodorizing apparatus (Japanese Patent Laid-Open No. 63-319023) having an operating condition of a space velocity of 8 m / sec.

After deodorizing in the apparatus, the result of measuring the concentration of the malodorous component in the exhaust gas (deodorizing performance) is shown in Table 1 below.

TABLE 1

As can be seen from Table 1, it can be seen that the gas treatment capacity of the deodorizing device (Example 1) of the present invention is far superior to the removal of odor gas components compared to the conventional deodorizing device (Comparative Example 1).

Example 2

As shown in Table 2 below, the gas containing a high concentration of malodorous components is deodorized under the same conditions as in Example 1 to measure the ability to remove the malodorous gas, but the results of dividing by periods are shown in Table 2 below.

TABLE 2

As can be seen from the above Table 2, the removal rate shows a high value of 99.4% or more even for a high concentration of malodorous gas, and it is understood that there is almost no decrease in treatment capacity depending on the period.

Claims (7)

A microorganism having a nozzle 6 for spraying down the washing water downward between the inlet conduit 8 through which the gas containing the malodorous component is introduced and an outlet 7 through which the deodorized gas is discharged, and a microorganism having the microorganisms decomposing the malodorous component fixed thereto. Deodorization tower (4) is provided with a neutralization reaction layer (5) for neutralizing the basic components of the reaction layer (4) and malodorous components, and a discharge port (9) through which the washing water passing through the reaction layers (4, 5) is discharged ( 1) and a odor gas deodorizing device composed of a storage tank (3) for storing the washing water, wherein two filters in which a ceramic ultrafiltration membrane is embedded between the outlet port (9) and the storage tank (3). A deodorizing device for odor gas, characterized by providing a filtration device (2) in which (2a, 2b) is connected in parallel. The filter (2a, 2b) according to claim 1, wherein the filter (2a, 2b) is the outlet (9), the nozzle (6), the reservoir (3) and the valve (V1, V2, V3, V4, V5, V6, V7, V8) characterized in that each connected to the installation. Device according to one of the preceding claims, characterized in that the filter (2a, 2b) is adapted for switching by the valve at intervals of 20 to 30 minutes from each other. While supplying the malodorous gas upward and supplying the washing water downward, neutralizing the basic components of the malodorous component in the neutralization reaction layer and then adsorbing the remaining malodorous component to the microorganisms in the microbial reaction layer and absorbing it in the washing water, and then degassed gas. In the deodorizing method of the odor gas used for storing and recycling the washing water passing through the microbial reaction layer and the neutralization reaction layer and recycled with the new athlete, the washing water passing through the microbial reaction layer and the neutralization reaction layer Deodorizing method of odorous gas, characterized in that the microorganisms are separated by using a filtration device with a built-in ceramic ultrafiltration membrane is recycled to the microbial reaction layer with the washing water. 5. The method according to claim 4, wherein said filtration device is connected in parallel with a first filter and a second filter. The method of claim 5 wherein said first filter separates microorganisms and said second filter is by recycling microorganisms. 7. The method according to claim 6, wherein the filters are switched to each other.