KR100440811B1 - Method and apparatus of treating organic waste water - Google Patents

Abstract

An object of the present invention is to provide a method for treating organic wastewater, which can improve the treated water quality without raising equipment cost.

According to the configuration of the present invention, after organic treatment of the organic wastewater in the biological treatment tank (2), the treatment liquid treated in the biological treatment tank (2) is separated into the treated water and sludge in the settling tank (4), While a part is returned to the biological treatment tank 2, the remaining sludge is solubilized by a thermophilic bacterium in the solubilization tank 7, and the process liquid after a solubilization process is returned to the biological treatment tank 2.

Description

Organic wastewater treatment method and treatment apparatus {Method and apparatus of treating organic waste water}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for treating organic wastewater discharged from organic wastewater, for example, sewage, urine, food factory, chemical plant, etc. using a biological reaction, and a treatment apparatus thereof.

Conventionally, as a general treatment method of this kind of organic wastewater, firstly, organic components in the organic wastewater are biologically digested by aerobic or anaerobic microorganism decomposition such as aerobic digestion and anaerobic methane fermentation, and the organic matter is carbon dioxide gas, methane gas or the like. And the treated liquid containing microbial biomass (mainly microbial cells) and untreated residual sludge produced by such biological digestion by solid-liquid separation in a sedimentation tank, etc. ) And the sludge is being treated in a proper manner. For example, as shown in FIG. 11, organic wastewater, such as sewage introduced into the biological treatment tank 2, may be carbon dioxide or the like by biooxidation, which is an oxidative decomposition reaction by microorganisms under aerobic conditions in the biological treatment tank 2, or the like. Wastewater treated with inorganic matters such as water and treated in the biological treatment tank 2 is solid-liquid separated into treated water (C) and sludge (D) in the settling tank (4), and a part of the sludge (D) is While being returned to the biological treatment tank 2 as a microbial source, the remaining sludge is generally treated as surplus sludge (E).

In this case, however, the precipitate solid concentrate (sludge) containing the organic sludge separated from the sedimentation tank 4 is subjected to a process such as concentration, digestion, dehydration, composting, and incineration. Cost and time were not desirable.

For this reason, as a processing method in which sludge does not come out as much as possible, it is an aeration tank; A long time aeration method for lengthening the residence time of the sludge in an aeration tank, or by attaching the sludge to the surface of the contact material, a catalytic oxidation method for retaining the sludge in a large amount in the reaction tank has been proposed and put into practical use. Published by the Japan Sewerage Association, supervised by the Ministry of Construction and Urban Affairs, Sewerage Department, sewer facility planning and design guidelines and commentary, 1994 edition). However, these methods require a large installation area as an aeration tank in order to lengthen the residence time of the sludge in the aeration tank. In addition, in the aeration method for a long time, the sludge diffusion occurs when the load is lowered, which impedes solid-liquid separation. Will result. In addition, the contact oxidation method was not preferable in that clogging of sludge occurred when the load was increased.

Therefore, in the activated sludge treatment method for treating organic sludge, Japanese Laid-Open Patent Publication No. Hei 9-276887 discloses an activated sludge treatment tank and an activated sludge treatment method. Solid-liquid separator for solid-liquid separation of sludge after treatment, sludge conveying means for returning a part of the separated sludge to an active sludge treatment tank, a heating device for warming the remaining sludge to 40 to 100 ° C, and heated sludge A method of treating organic sewage using an apparatus having sludge conveying means for conveying to a treatment tank. However, in the method described in the above publication, since solubilization of sludge in the heating device is performed only by heating, the solubilization treatment liquid contains a large amount of BOD components, and this high BOD component is not inorganicized and remains in the solubilization treatment liquid as it is. When the solubilization treatment liquid containing a large amount of this BOD component is returned to the activated sludge treatment tank, the organic material load in the activated sludge treatment tank is excessive, and the oxidative decomposition of organic matter in the activated sludge treatment tank is insufficient. As a result, the water quality of the treated water is deteriorated.

Therefore, it is considered to increase the residence time of the liquid to be treated in the activated sludge treatment tank, that is, increase the volume of the activated sludge treatment tank in response to the increase in the BOD load by the solubilization treatment. Will result.

This invention is made | formed in view of such a problem which the prior art has, and the objective is to provide the processing method of organic wastewater and its processing apparatus which can improve the treated water quality, without raising an installation cost. Another object of the present invention is to provide a method for treating organic wastewater and an apparatus for treating the wastewater, which can significantly reduce the amount of surplus sludge generated.

In order to achieve the above object, the present invention solubilizes sludge by solubilizing the sludge, thereby reducing the sludge by solubilization and at the same time, the organic matter in the solubilizing treatment liquid is decomposed by the thermophilic bacterium. The BOD of the treatment liquid can be lowered.

1 is a schematic configuration diagram of an embodiment of an organic wastewater treatment apparatus to which the method for treating organic wastewater of the present invention can be applied.

2 is a schematic configuration diagram of another embodiment of an organic wastewater treatment apparatus to which the method for treating organic wastewater of the present invention can be applied.

3 is a schematic structural diagram of still another embodiment of an organic wastewater treatment apparatus to which the method for treating organic wastewater of the present invention can be applied.

4 is a view showing the change in solubilization rate according to the difference in the concentration of sludge.

5 is a view showing a change in protease activity according to the difference in the concentration of sludge.

6 is a view showing changes in solubilization temperature and solubilization rate.

7 is a schematic structural diagram of still another embodiment of an organic wastewater treatment apparatus to which the method for treating organic wastewater of the present invention can be applied.

8 is a schematic structural diagram of yet another embodiment of an organic wastewater treatment apparatus to which the method for treating organic wastewater of the present invention can be applied.

9 is a schematic structural diagram of yet another embodiment of an organic wastewater treatment apparatus to which the method for treating organic wastewater of the present invention can be applied.

10 is a schematic structural diagram of still another embodiment of an organic wastewater treatment apparatus to which the method for treating organic wastewater of the present invention can be applied.

11 is a schematic configuration diagram of a conventional organic wastewater treatment apparatus.

<Brief description of the main parts of the drawing>

2, 2c biological treatment tank 4 sedimentation tank

7, 7a solubilization tank 9 thickener

In the method of biologically treating organic wastewater, the organic wastewater is subjected to biotreatment in a biotreatment apparatus, and a part of the sludge in the biotreatment apparatus is solubilized by thermophilic bacteria in a solubilization treatment apparatus and treated after solubilization treatment. The summary of the method for treating organic wastewater is characterized by returning the liquid to the biological treatment device.

Here, as the biotreatment apparatus, any type of aerobic biotreatment or anaerobic biotreatment can be applied. The aeration treatment apparatus used for aerobic biological treatment may be an aeration method or a mechanical aeration method as long as it is provided with an aeration means. The aeration treatment is carried out at room temperature with an aeration amount of preferably 0.1 to 0.5 vvm (vvm = aeration amount / aeration capacity / min) so as to allow aerobic oxidative decomposition, but depending on the load, the aeration amount is higher than this, and at a higher temperature. You may process it. The liquid to be treated is preferably adjusted to 5.0 to 8.0 pH. In addition, in order to promote aerobic digestion and decomposition, aeration treatment apparatuses may be added with microorganisms such as yeast and flocculants such as aluminum sulfate, polyaluminum chloride, ferric chloride and ferrous sulfate to promote floc formation. The aerobic biotreatment may be a device capable of aerobic treatment other than the aeration treatment apparatus. [0016] As the apparatus used for the anaerobic biotreatment, a method of stirring by circulating a liquid in a water tank, a method of stirring by circulating aeration of a product gas, It can be used as long as it has a means for efficiently contacting the active microorganism with the organic wastewater to be treated, such as a method for installing a stirrer such as a stirring blade or a method having an active microorganism fixing means.

In the solubilization step, the sludge is decomposed by thermophilic bacteria (for example, bacteria such as Bacillus stearothermophilus may be added), but enzymatic degradation (for example, protease, You may carry out in combination with various methods, such as a lipase, glycosidase, etc. added individually or in combination.

As solubilization conditions in the solubilization treatment apparatus, in order to promote solubilization by sludge solubilizing enzyme and heat secreted by thermophilic bacteria, for example, the following conditions can be adopted.

(1) Temperature: 50-90 degreeC, Preferably it is 55-75 degreeC, More preferably, it is 60-70 degreeC

(2) sludge concentration: 1000 mg / liter or more, preferably 3000 mg / liter or more, more preferably 5000 to 25000 mg / liter

(3) pH: 6-9, preferably 7-8.5, more preferably 7-8

(4) Environment: aerobic or unbreathing conditions

(5) Duration of stay: Determined based on hydrodynamic retention time (also known as HRT) based on solubilization rate and degree of degradation of sludge. The HRT is obtained based on the amount of inflow liquid and the effective volume of the reaction tank, and is expressed by the following relationship.

HRT = reactor volume (liters) / influent volume per unit time (liters / hr)

According to the present invention, since the solubilization of the sludge is performed by thermophilic bacteria in the solubilization treatment apparatus, since the soluble organic matter is decomposed and inorganicized by the thermophilic bacteria at the same time as the loss of the sludge by solubilization, the BOD of the solubilization treatment liquid is lowered. It is possible to reduce the biological load of the treatment liquid returned to the biological treatment device, thereby improving the treated water quality.

Moreover, decomposition | disassembly of sludge by thermophilic bacteria is performed favorably, and the specific conditions which can improve a treated water quality are as follows.

If the HRT in the solubilization treatment apparatus is short, it is not preferable because the organic matters are not sufficiently decomposed (not inorganicized) and the BOD of the treatment liquid returned to the biotreatment apparatus cannot be lowered. On the other hand, a long HRT in the solubilization treatment device is not preferable because a substance that inhibits the growth of thermophilic bacteria is accumulated. In this regard, it is preferable that the hydraulic residence time for solubilization in the solubilization treatment device is 2 to 8 days. In order to control the HRT, a concentrating means is provided in front of the solubilization treatment apparatus to concentrate the sludge, and a method of changing the amount of sludge to be input to the solubilization treatment apparatus, and a liquid level sensor which detects the level of the treatment liquid in the solubilization treatment apparatus. In this way, the HRT can be controlled by a method of adjusting the liquid level in the solubilization processing apparatus by the liquid level sensor.

The pH of the solubilization treatment liquid in the solubilization treatment apparatus is preferably in the range of 6 to 9 suitable for the growth of thermophilic bacteria, and more preferably in the range of 7 to 8.5 suitable for the secretion and activity of sludge solubilizing enzyme. It is still more preferable to set it as the range of -8. In order to adjust the pH, a pH sensor is installed in the treatment liquid path immediately before flowing into the solubilization treatment apparatus or the solubilization treatment apparatus, and the pH sensor is detected by changing the pH by appropriately adding acid or alkali to the treatment liquid. PH can be adjusted.

It is preferable to control the temperature of the solubilization treatment liquid in the solubilization treatment apparatus at 55 to 75 ° C. suitable for the growth of thermophilic bacteria. In this case, when the solubilization temperature is low, the activity of thermophilic bacteria is insufficient, and a sufficiently high solubilization rate may not be obtained. On the other hand, if the solubilization temperature is too high, even if physicochemical thermal decomposition by heat proceeds, the activity of thermophilic bacteria decreases, so that a high solubilization rate cannot be obtained and, in some cases, a lower solubilization rate than without thermophilic bacteria. There is also. Therefore, as shown in detail in Examples later, by solubilizing sludge by microbial treatment with thermophilic bacteria at 60 to 70 ° C, very high solubilization rate can be obtained.

In addition, the treatment liquid treated in the biological treatment apparatus is separated into treated water and sludge in the solid-liquid separator, and a part of the sludge is returned to the biological treatment apparatus, and the remaining sludge is solubilized by thermophilic bacteria in the solubilization treatment apparatus. Thereafter, the solubilization treatment liquid may be returned to the biological treatment device. The solid-liquid separator means, for example, a precipitation apparatus, a flotation separator, a centrifugal separator, a membrane separator, and the like.

In addition, in order to reduce the amount of treatment sludge in the solubilization treatment apparatus, a concentrator may be provided in the path from the solid-liquid separator to the solubilization treatment apparatus. In this case, if a part of sludge separated in the solid-liquid separator is returned to the bioprocessing apparatus, and at least a part of the remaining sludge is concentrated in the concentrator, and then solubilized by thermophilic bacteria in the solubilization treatment apparatus, separation in the solid-liquid separator is performed. Since at least a part of the sludge is concentrated in a concentrator and then sent to a solubilization treatment apparatus, nutrition conditions suitable for the growth of thermophilic bacteria can be obtained, and solubilizing enzymes are also produced, whereby a high solubilization rate can be obtained. In addition, since at least a portion of the sludge is concentrated and then sent to the solubilization treatment apparatus, the amount of treatment sludge sent to the solubilization treatment apparatus is reduced, so that the solubilization treatment apparatus can be miniaturized.

In addition, if the sludge separated by the solid-liquid separator is concentrated in a concentrator, then a part of the sludge is returned to the bioprocessing apparatus, and at least a part of the remaining sludge is solubilized by thermophilic bacteria in the solubilization treatment apparatus. Since the sludge separated in step 2 is concentrated and a part of the sludge after concentration is sent to the solubilization treatment device, the high solubilization rate can be secured and the solubilization treatment device can be miniaturized as described above. Part of the sludge is sent to the bioprocessing device after concentration, so that the amount of microorganisms in the bioprocessing device is increased, and it is possible to maintain a high concentration of microorganisms in the bioprocessing device, and the decomposition reaction of organic matter by the microorganism is sufficiently performed. As a result, the sludge load is reduced, resulting in an improved treatment water quality. The.

In particular, as shown in detail in the later-described examples, the solubilization process is more efficiently because the nutrient conditions suitable for the growth of thermophilic bacteria can be obtained by concentrating the sludge to 99% or less of water content (1% or more of sludge concentration). It is possible to further reduce the solubilization treatment apparatus.

<Example>

An embodiment of the present invention will be described below. 1 is a schematic configuration diagram of an embodiment of an organic wastewater treatment apparatus to which the method for treating organic wastewater of the present invention can be applied.

As shown in FIG. 1, the raw wastewater A is introduced into the biological treatment tank via the path 1, and the raw wastewater, which is an organic wastewater, is aerobic biotreated in the biological treatment tank 2. In addition, aerobic biotreatment means that organic matter is decomposed into inorganic substances such as carbon dioxide or water by biooxidation, and aerobic microorganisms used are Gram-negative or Gram-positive bacillus used in activated sludge method for sewage purification, for example. , Pseudomonas (Pseudomonas) and Bacillus (bacillus), these inoculated cells are obtained from a conventional sewage purification treatment facility. In this case, although the temperature of the biological treatment tank 2 is operated so that it may become a temperature range of 10-50 degreeC, normally 20-30 degreeC, in order to process more efficiently, a high temperature is preferable, for example, it is a waste water excess. In the case of using mesophilic bacteria separated from, it is operated in the temperature range of 35 ~ 45 ℃. In any case, the optimum temperature conditions are selected and operated from the above temperature ranges so that the oxidative decomposition reaction by the microorganisms occurs efficiently and sufficiently. In this case, either the batch type or the continuous type can be used as the biological treatment tank 2.

Subsequently, the treated water B treated in the biological treatment tank 2 is introduced into the sedimentation tank 4 as a solid-liquid separator after passing through the path 3, and the liquid-liquid separated supernatant C is discharged. In accordance with the emission standard, it is subjected to tertiary treatment such as supernitrification or ozone treatment, if necessary, and used as a stream discharge or hydroponic water.

On the other hand, a part of the sludge (D), which is an organic solid separated from the settling tank (4), passes through the path (5) and joins the path (1) to be introduced into the biological treatment tank (2) together with the raw waste water (A). . In addition, the amount of sludge sent through the path 5 is determined by the amount of microorganisms retained in the biological treatment tank 2.

In addition, the remaining sludge E separated from the settling tank 4 is introduced into the solubilization tank 7 through the path 6. In the solubilization tank 7, solubilization of organic solids is performed aerobicly at high temperature conditions. In this case, inoculated cells (aerobic bacteria) of aerobic microorganisms used at high temperature are obtained by culturing the microorganisms in, for example, a conventional aerobic digester. In addition, the optimum temperature of the solubilization tank 7 is preferably operated under the conditions of the temperature range of 50 to 90 ° C, but depending on the type of thermophilic bacteria that decomposes the organic solids contained in the sludge (E), which is the target of the high temperature treatment. In the case of thermophilic bacteria isolated from sewage sludge, for example, solubilization reaction by microorganisms (thermococci) and physicochemical thermal decomposition by heat occur efficiently and sufficiently at the same time under high temperature conditions. The temperature is in the range of 55 to 75 ° C and the enzyme activity is most preferably operated at 60 to 70 ° C. In any case, the temperature range of 50 to 90 ° C. may be set in accordance with the type of microorganism so that both the solubilization reaction by microorganisms (thermococci) and the physicochemical pyrolysis due to heat are sufficiently and efficiently generated at the same time.

Moreover, as an apparatus for aerobic microorganism treatment in the solubilization tank 7, it can be used if it is provided with the conventional acid pipe. In this case, either a batch type or a continuous type can be used as a solubilization tank.

In this way, the treatment liquid F solubilized in the solubilization tank 7 joins the path 1 via the path 8 and is introduced into the biological treatment tank 2 together with the raw waste water A to perform the biological treatment. All.

Next, solubilization conditions (aerobic conditions by addition of aerobic thermophiles and anaerobic conditions without addition of aerobic thermophiles) and changes in solubilization rate and treated water quality of the case of HRT of 1 or 2 days were examined. The results of investigating the change of solubilization rate and the change of protease activity according to the difference in the concentration ratio of, and the results of the change of solubilization temperature and solubilization rate are explained.

(1) Investigation of solubilization rate

After the bacterium of Bacillus stearloader Mophilus SPT2-1 [FERMP-15395], which is aerobic thermophilic bacteria precultured, was incubated in a surplus sludge derived from a sewage treatment plant having an organic solid concentration of 2% by weight, Into an effective volume of 2 liter glass jar fermenter, treated at 65 ° C. with aeration rate of 1.0 liter / min. And stirring speed of 300 rpm (redox potential = 50-100 mV, pH = 8.1), HRT = Solubilization samples are taken for 1 day or 2 days, and the volatile solids content (VSS ₁ ) is measured. Based on the volatile solids content (VSS ₀ ) before treatment, the solubilization rate (%) in each HRT according to the following equation. Was measured. Measurement of these VSS VSS ₀ and ₁ was carried out according to JIS-K-0102. At the same time, the solubilization rate was investigated when the HRT was 1 day under anaerobic conditions (no aerobic thermophile) at the above solubilization temperature using the sludge.

Solubilization rate (%) = ((VSS _0- VSS ₁ ) / VSS ₀ ) x 100

As a result, the results shown in Table 1 below were obtained.

Anaerobic conditions Aerobic conditions (with thermophilic bacteria) HRT 1 day 1 day 2 days Solubilization rate (%) 24 39 47 BOD of solubilized solution (mg / liter) 4850 2700 1500 BOD (kg) / dissolved volatile solids (kg) 0.97 0.34 0.17

As Table 1 shows, when the HRT is 1 day, the BOD of the treatment solution is reduced to about 55% when the solubilization by aerobic thermophilic bacteria is performed compared to the BOD of the treatment solution when the solubilization is performed by anaerobic conditions. okay. Moreover, when solubilizing by aerobic thermophilic bacteria was performed by HRT = 2 days, it turned out that BOD of a process liquid is reduced to about 30% compared with the case of solubilization by anaerobic conditions.

(2) change in treated water quality

In order to construct the apparatus shown in FIG. 1, as the biological treatment tank 2, each tank made of a transparent vinyl chloride resin having an effective volume of 40 liters having a cross-sectional area of 800 cm2 and a height of 60 cm is used. 2) at 25 ° C. at 10 liters / min. The aeration tank 4 uses a lower pyramidal pyramid made of transparent vinyl chloride resin having an effective volume of 7 liters with a cross-sectional area of 400 cm2 and a height of 40 cm. The solubilization tank 7 has an inner diameter of 13 cm and a height of 25 cm. Using a 2 liter glass cylinder of effective volume and the characteristics of the organic wastewater, using a peptone: glucose: yeast extract = 4: 4: 1, the biotreatment tank was loaded at 0.4 kgBOD / m ³ / day. The amount of sludge entering the path 5 is adjusted so that the sludge concentration of (2) is about 3000 mg / liter, and in the solubilization tank 7, the solubilization treatment under aerobic conditions by addition of the aerobic thermophile described above (65). ℃, aeration rate 1.0 liter / min., Stirring rate 300rpm, redox potential = 50-100mV, pH = 8.1) and the solubilization treatment (65 ℃) by heat only under anaerobic conditions. Investigate.

As a result, the results shown in Table 2 below were obtained.

Anaerobic conditions Aerobic conditions (with thermophilic bacteria) HRT 1 day 1 day 2 days BOD of treated water (mg / liter) 12 <5 <5 SS of treated water (mg / liter) 18 7 8

As can be seen from Table 2, it was found that the water quality of the treated water is greatly improved by solubilizing with aerobic thermophile.

In addition, by concentrating the sludge, the amount of sludge injected into the solubilization tank is reduced, and as a result, the HRT is also long in the solubilization tank, so that the amount of BOD of the treatment liquid returned from the solubilization tank to the biological treatment tank can be greatly reduced. For example, as shown in FIG. 2, the processing apparatus which added the concentrating apparatus 9 to the apparatus of FIG. 1 can be used. As the concentrating device 9, a concentrating device such as membrane concentration, centrifugal concentration, flotation concentration, evaporation concentration, and flow ring lamination concentration can be used.

In addition, as shown in FIG. 3, after all the sludges D separated in the settling tank 4 are concentrated in the concentrator 9, a portion of the sludge is returned to the biological treatment tank 2 through the path 5. The remaining sludge may be solubilized by thermophilic bacteria in the solubilization tank 7.

(3) Changes in solubilization rate and protease activity according to the difference in concentration of sludge

5L (liter) glass jar fermenter is used as the solubilization tank, and surplus sludge collected from the final sedimentation basin of the sewage treatment plant is used as the sludge to be treated at various concentrations, and 2L (liter) of the sludge concentration adjusted to the solubilization tank is used. 1% of the thermophilic bacteria culture medium was added at a volume ratio, and the solubilization treatment was carried out for 24 hours at 1 A / min of aeration, 300 rpm, and a temperature of 65 ° C., so that the VSS (organic solids) solubilization rate and sludge solubilizing enzyme after 24 hours. The protease activity which was one of was measured. The results are shown in FIGS. 4 and 5. The VSS solubilization rate (%) is defined by the following equation when the volatile solids content after incubation for 24 hours is VSS ₁ and the volatile solids content before incubation is VSS ₀ , and the measurement of VSS ₁ and VSS ₀ is JIS-K-0102. Followed.

VSS solubilization rate (%) = ((VSS _0- VSS ₁ ) / VSS ₀ ) x 100

As shown in Fig. 4, it was found that remarkably high solubilization rate was obtained by concentrating sludge to 99% or less of water content (1% or more of sludge concentration). In addition, as shown in FIG. 5, it was found that protease activity that supports the solubilization rate was high at a water content of 99% or less (a sludge concentration of 1% or more). Thus, the solubilization rate can be remarkably improved by concentrating sludge to 99% or less of water content. That is, for the proliferation and activity of aerobic thermophiles in a solubilization tank equipped with aeration means, it is necessary to dissolve organic matter in the solubilization tank as a nutrient source of thermophilic bacteria. By adding to the solubilization tank, the concentrated sludge is solubilized by sludge solubilizing enzyme of aerobic thermophilic bacteria present in the heat and solubilizing tank, and the solubilizing solution is a substrate sufficient for growth of aerobic thermophilic bacteria in the solubilization tank and production of sludge solubilizing enzyme ( Aerobic thermophiles are sufficiently grown to maintain high activity. Since a large amount of sludge solubilizing enzyme is produced | generated and secreted by this, the solubilization reaction by aerobic thermophile is fully and continuously performed, and it becomes possible to ensure high solubilization rate.

On the contrary, when the sludge concentration was added to the solubilization tank at 1% or less (99% or more water content), the substrate necessary for the growth of aerobic thermophiles and the production of sludge solubilizing enzymes was insufficient. You can only expect to some extent, and you cannot achieve high solubilization rates. In addition, even if the sludge is concentrated to 90% or less of water content, the above advantages cannot be obtained. On the contrary, the fluidity deteriorates, and when the solubilizing tank is operated in an exhaled or unexpired air, foaming phenomenon occurs due to aeration. The concentration of sludge by the concentrator is preferably in the range of 90% to 99% of water content. In particular, in the case of aerobic conditions, the water content of sludge is preferably in the range of 96 to 99%.

(4) solubilization temperature and solubilization rate

As the target sludge, the sludge collected from the aeration tank of the sewage treatment plant was concentrated to 1.5% by gravity concentration. 150 ml of each of the concentrated sludge was added to five 500 mL bevel inlet flasks, and the whole culture was spawned as a seed. (Previous) 5 mL of the aerobic thermophilic bacillus Bacillus stearerder Mophilus SPT2-1 strain [FERMP-15395] was added and incubated at each set temperature for 24 hours, and VSS was measured while supplying the evaporated water. . In FIG. 6, temperature (degreeC) is set on the horizontal axis, and VSS solubilization rate (%) is shown on a vertical axis.

For comparison, an experiment was also conducted in which the thermophilic bacteria were solubilized without adding the thermophilic bacteria to the concentrated sludge using the concentrated sludge.

The symbol "(circle)" in FIG. 6 shows the case where thermophilic bacteria were put in solubilization, and the symbol "(circle)" shows the case where solubility was solubilized without thermophilic bacteria.

As can be seen from FIG. 6, solubilization can be remarkably improved by solubilizing the microorganism by thermophilic bacteria at 60 to 70 ° C. However, below 60 ° C., the activity of thermophilic bacteria is insufficient, and a sufficiently high solubilization rate cannot be ensured. On the other hand, if the solubilization temperature is higher than 70 ° C., the activity of thermophilic bacteria decreases even if physicochemical pyrolysis by heat proceeds, so that a high solubilization rate cannot be obtained, and in some cases, a lower solubilization rate than that without thermophilic bacteria. In some cases.

In addition, another embodiment of the organic wastewater treatment apparatus to which the treatment method of the organic wastewater of the present invention can be applied will be described with reference to FIGS. 7 to 10.

7 shows an example in which the membrane separation apparatus 10 is provided in the biological treatment tank 2, and solid-liquid separation by the membrane separation apparatus is performed in parallel with the biological treatment. In the membrane separation apparatus 10 installed in the biological treatment tank 2, for example, a membrane having a pore diameter of 0.1 to 2.5 µm, preferably 0.3 to 0.5 µm may be used, and is formed in one or more membrane module structures. It is suitable to be. As a preferable membrane separation apparatus, the immersion type membrane separation apparatus provided with the T-type filter element made from Yuasa Co., Ltd., etc. are mentioned. In addition, the membrane separation apparatus preferably includes or includes cleaning means by pressurization by water pressure, air pressure, or the like, and by friction, vibration, or chemical injection, so that a substance that does not pass through the membrane can adhere to the membrane surface. It is enough to avoid the structure. The sludge is removed in the biotreatment tank 2 to add a portion of the treatment liquid to the next solubilization process. Preferably, the suspended solids concentration (MLSS) in the biotreatment tank 2 is constant, for example, 10000 to 20000 mg. The sludge may be taken out while controlling the amount intermittently or normally so that it is kept at / liter and the digestion and decomposition by an aerobic treatment can be performed smoothly, and it is sent to the next solubilization process. It is also possible to concentrate the sludge removed from the biological treatment tank by a concentrating device before it is added to the solubilization step.

Fig. 8 shows an example in which phosphorus components in organic wastewater are removed by microorganisms. Phosphorus release is carried out by microorganisms in an anaerobic tank 2a. Next, aerobic microbial digestion and Intake of phosphorus by microorganisms (internal storage) is performed. Subsequently, the biotreated treatment liquid is separated into a primary sludge (x) and primary treated water (a) in which phosphorus components are concentrated in the precipitation tank 4. In order to release the phosphorus component from the microorganisms in the primary sludge (x), in the following phosphorus release device 11, the phosphorus component is released into the liquid phase by anaerobic treatment, heat treatment, sonication, ozone treatment, alkali treatment, etc. The sedimentation, flotation, centrifugation, and membrane separation (including dehydrator separation) are used to separate the secondary phosphorus-containing water (b) and the secondary sludge (z). In this case, the phosphorus release is preferably anaerobic treatment and heat treatment (60 to 90 ° C.), and the solid-liquid separation is preferably sedimentation separation and flotation separation. Subsequently, a flocculant is added to the secondary treated water (b), and in the phosphorus separator 12, the phosphorus component is aggregated as a solid component, whereby the tertiary treated water c and the solid toughness that do not substantially contain the phosphorus component are included. Get the minute y. This solid phosphorus component (y) can be used as a raw material for producing fertilizers and phosphorus compounds. The secondary sludge (z) is solubilized in the solubilization tank 7 to further reduce the sludge component.

FIG. 9 is an example of the case where the loss of thermal energy is small, the nitrogen-containing organic component or the nitrogen-containing inorganic component in the treated water discharged out of the treatment system is small, and the odor removal of the exhaust gas dissipated in the air is possible. Nitrogenizer and denitrification apparatus 14 are disposed in the treatment liquid path leading to the tank 2, and a part of the sludge separated from the settling tank 4 passes through the reflux path 15 to the nitrogenizer ( 13), the treatment liquid solubilized in the solubilization tank 7 is conveyed to the denitrification apparatus 14 through the heat exchanger 16 and the conveying path 17. In addition, the air entering the solubilization tank 7 through the path 18 enters the nitrogenizer 13 through the path 19. The NH ₄ ⁺ component in the organic wastewater is changed to NO ₂ ⁻ or NO ₃ ⁻ by nitrifying bacteria in the nitrogenizer 13, and the NO ₂ ⁻ or NO ₃ ⁻ is denitrified in the denitrification apparatus 14. And N ₂ by the action of the hydrogen donor. Since the gas (mainly NH ₃ containing gas) discharged from the solubilization tank 7 is dissipated into the atmosphere after being introduced into the nitrogenizer 13, the smell of the gas dissipated into the atmosphere is significantly weakened, and the solubilization tank ( Since the heat of the gas discharged from 7) is effectively used for the nitrification treatment in the nitrogenizer 13, there is little loss of thermal energy. In addition, the nitrogen-containing organic component or the nitrogen-containing inorganic component in the treated water discharged out of the treatment system is substantially zero. When there is not much organic content in raw water, as shown in FIG. 9, it is preferable to denitrify in a denitrification apparatus after nitrogenizing in a nitrogenizer.

However, when the organic matter in the raw water is large, the microorganisms which oxidatively decompose the organic matter increase and the nitrification of the nitrifying bacteria is inhibited. Therefore, the organic matter in the raw water is first removed in the denitrification apparatus, and then nitrogen is removed. In the apparatus, it is preferable to carry out the nitrogenization treatment by nitrification bacteria. Then, by returning the treatment liquid after the nitrification treatment to the denitrification apparatus, treated water containing almost no nitrogen component can be discharged to the outside from the precipitation tank 4.

Fig. 10 shows an example in which the amount of supply air can be reduced when biologically treating organic wastewater. The solubilization tank 7a is sealed and a compressor 20 is installed near the solubilization tank 7a. By the high pressure air entered into the solubilization tank 7a in the compressor 20, the processing liquid after the solubilization process is introduced into the biological treatment tank 2c together with the high pressure air through the conduit 21, so that the solubilization tank 7a. ), The high pressure air is introduced, so that the oxygen dissolution efficiency in the solubilization treatment liquid in the solubilization tank 7a is increased, so that the amount of supply air can be reduced, and the amount of heat retained in the solubilization tank coming out of the atmosphere together with the exhaust gas can be reduced. . In this case, it is also possible to introduce the processing liquid of the solubilization tank 7a into the biological treatment tank 2c separately from the high pressure air. By supplying a gas having heat from the solubilization tank 7a to the biological treatment tank 2c, the biological activity of the biological treatment tank 2c is increased, and the quality of the treated water can be improved.

Since the present invention is configured as described above, the following effects can be obtained.

According to the invention of claim 1, since the soluble organic matter is decomposed and inorganicized by thermophilic bacteria with the reduction of the sludge by solubilization, it is possible to simultaneously achieve the compactness of the biological treatment apparatus and the improvement of the treated water quality.

According to the invention described in claims 2 to 4, conditions suitable for the growth of thermophilic bacteria appear, and the treated water quality can be greatly improved.

According to the invention of Claims 5 and 6, it is possible to secure a very high solubilization rate, to significantly reduce the amount of surplus sludge generated, and to further downsize the solubilization treatment apparatus.

According to invention of Claim 7, Claim 8 can provide the processing apparatus suitable for implementing the processing method of Claim 1-Claim 4.

According to the invention described in claim 9, it is possible to provide a processing apparatus suitable for carrying out the processing methods of claims 5 and 6.

Claims (15)

A method of biologically treating organic wastewater, wherein organic wastewater is biotreated in a biotreatment apparatus, and a portion of sludge in the biological treatment apparatus is hydrolyzed by aerobic thermophilic bacteria in a solubilization treatment apparatus. A method for treating organic wastewater, characterized in that the solubilization time is 2 to 8 days, and the treatment liquid after solubilization is returned to the biological treatment device. delete The method for treating organic wastewater according to claim 1, wherein the pH of the solubilization treatment liquid in the solubilization treatment apparatus is 6 to 9. The method for treating organic wastewater according to claim 1 or 3, wherein the temperature of the solubilization treatment liquid in the solubilization treatment apparatus is controlled to 55 to 75 占 폚. The method for treating organic wastewater according to claim 1 or 3, wherein the water content of the sludge introduced into the solubilization treatment device is 99% or less. The method for treating organic wastewater according to claim 5, which is solubilized at 60 to 70 DEG C by thermophilic bacteria in a solubilization treatment apparatus. delete delete delete A device for biologically treating organic wastewater, Organic wastewater is biotreated with a biotreatment device to ingest phosphorus components by microorganisms, and the biotreated treatment liquid is separated into primary sludge and primary treated water in which phosphorus components are concentrated in a solid-liquid separator. Is separated into secondary treated water and secondary sludge containing phosphorus in the phosphorus discharge device, and secondary treated water containing high phosphorus component is separated into tertiary treated water that is substantially free of solid phosphorus and phosphorus in the phosphorus separation device. And the secondary sludge is solubilized by a solubilization treatment device, and the treatment liquid after the solubilization treatment is returned to the biological treatment device. As a method of biologically treating organic wastewater, The organic wastewater is nitrified with a nitrify apparatus and then denitrified with a denitrification apparatus. The organic wastewater after denitrification is biotreated with a biotreatment apparatus. A method for treating organic wastewater, characterized in that the sludge is separated into treated water, a part of the sludge is solubilized by a solubilization treatment device, and the treated liquid after solubilization is returned to the biological treatment device. As a method of biologically treating organic wastewater, The organic wastewater is denitrified by a denitrification apparatus, followed by nitriding with a nitrification apparatus. The organic wastewater after nitrification is biotreated with a biotreatment apparatus, and the biotreated treatment liquid is separated into sludge and treated water in a solid-liquid separator. And a part of the sludge is solubilized by a solubilization apparatus, and the treatment liquid after solubilization is returned to the biological treatment apparatus. A device for biologically treating organic wastewater, A biotreatment device comprising an anaerobic tank and an aerobic tank for biotreating organic wastewater; A solid-liquid separator for separating the biotreated treatment liquid into primary sludge and primary treated water concentrated with phosphorus; Phosphorous discharge device for separating the primary sludge into a high phosphorus secondary treatment water and secondary sludge; A phosphorus separation device for separating the phosphorus-containing secondary treated water into tertiary treated water substantially free of solid phosphorus and phosphorus; And a solubilization treatment device for solubilizing the secondary sludge. A device for biologically treating organic wastewater, A denitrification apparatus for denitrification subsequent to a nitrification apparatus for nitrifying organic wastewater; A biotreatment apparatus for biotreating organic wastewater after denitrification; A solid-liquid separator for separating the biotreated treatment liquid into sludge and treated water; Solubilization treatment apparatus for solubilizing a portion of sludge; organic wastewater treatment apparatus. A device for biologically treating organic wastewater, A nitriding device for nitriding subsequent to a denitrification device for denitrifying organic wastewater; A biotreatment apparatus for biotreating organic organic wastewater after nitrification; A solid-liquid separator for separating the biotreated treatment liquid into sludge and treated water; Solubilization treatment apparatus for solubilizing a portion of sludge; organic wastewater treatment apparatus.