JPH09122688A - Treatment of selenium-containing water - Google Patents

Abstract

PROBLEM TO BE SOLVED: To remove selenium compounds from selenium-containing water stably at high efficiency and consequently obtain treated water of low selenium concentration. SOLUTION: A first anaerobic treatment tank 1 and a second anaerobic treatment tank 3 are installed to carry out anaerobic treatment of raw water 11 in multi-stages. In this case, a first solid liquid separation tank 2 and a second solid liquid separation tank 4 are installed and while biological sludge produced by the anaerobic treatment in one tank is prevented from moving to the anaerobic treatment process in the other tank, each anaerobic treatment is carried out by using biological sludge in respectively independent biological phases.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a method of contacting selenium-containing water with biological sludge in an anaerobic state to reduce selenium, and adsorbing an insolubilized selenium compound to the biological sludge to remove it.

[0002]

2. ^{Description of the Related} Art As a treatment method for detoxifying waste water containing selenium compounds such as Se ⁶⁺ and Se ⁴⁺ , there is a biological treatment method in which selenium-containing water is brought into contact with biological sludge in an anaerobic state to reduce the selenium compound. is there. For example, as a biological reaction of selenium compounds, the Annual Meeting of the Japan Society on Water Environment, 1995, P176
^Have reported that Se ⁶⁺ and Se ⁴⁺ are reduced in the presence of lactose by a (sub) selenate-reducing bacterium. This method can be used from a place contaminated with selenium compounds,
It is used to separate (sub) selenate-reducing bacteria and reduce selenium compounds. In addition to this, denitrifying bacteria, sulfate-reducing bacteria, acid-producing bacteria are used to reduce selenium compounds under anaerobic conditions. can do.

In such an anaerobic treatment, the selenium compound is insolubilized by reduction and adsorbed on the biological sludge, so that the selenium compound is removed by separating and discharging the sludge by solid-liquid separation. The reduction of selenium compounds requires the presence of organic matter as a substrate, and since excess organic matter remains after the anaerobic treatment step, the treatment liquid after anaerobic treatment is aerobically treated to decompose excess organic matter. There is also.

[0004]

By the way, in the above treatment, the selenium compound reduced and insolubilized in the anaerobic treatment step is adsorbed and removed by the biological sludge, but depending on the operating conditions, for example, the amount of raw water decreases and the anaerobic treatment is carried out. If the residence time is prolonged or the amount of organic substances added for removing selenium is too large, the removal of selenium becomes unstable, and the selenium concentration in the treated water cannot be lowered sufficiently. In addition, there are cases where the selenium concentration in the treated water does not become sufficiently low in cases other than the above operating conditions, and the cause thereof is unknown, so optimization of operating conditions alone cannot deal with it.

An object of the present invention is to propose a method for treating selenium-containing water, which enables stable and efficient removal of selenium compounds and thereby obtains treated water having a low selenium concentration.

[0006]

The present invention is directed to a first anaerobic treatment step of reducing selenium by bringing selenium-containing water into contact with biological sludge in an anaerobic state, and treated water anaerobically treated in the first anaerobic treatment step. And a second anaerobic treatment step of reducing selenium by contacting the anaerobic state with biological sludge in an anaerobic state, and the anaerobic treatment step is performed so that the biological sludge in one anaerobic treatment step does not move to the other anaerobic treatment step. It is a method for treating selenium-containing water, which is characterized by anaerobic treatment using biological sludge of independent biota.

In the present invention, "(selen) selenic acid" means "selenic acid and / or selenious acid". Also, “Se ⁶⁺ ”, “Se ⁴⁺ ”, “Se ⁰ ”, or “S
e ^2- "means each oxidation number + VI, + IV, zero or-
II means selenium. These may be simply described as Se. Further, in the present invention, “(nitro) nitric acid” means “nitric acid and / or nitrous acid”.

In the present invention, the selenium-containing material to be treated is contained.
Water is Se⁶⁺And / or Se ⁴⁺Of selenium compounds
It includes wastewater and other water. Se⁶⁺Or Se⁴⁺The selection
Examples of the phosphorus compound include (sub) selenic acid. Ingredient
As physical selenium-containing water, metal smelting industry wastewater, glass
Industrial wastewater, chemical industrial wastewater, coal or petroleum combustion exhaust gas treatment
Examples include wastewater in the physical process. Containing these selenium
In addition to selenium compounds, organic matter, nitrogen compounds,
An acid salt or the like may be contained.

In the present invention, such selenium-containing water is brought into contact with the anaerobic biological sludge in an anaerobic state in the first anaerobic treatment step to perform anaerobic treatment to reduce the selenium compound, and then the second anaerobic treatment. In the step, the anaerobic treated water that has been anaerobically treated in the first anaerobic treatment step is brought into contact with the anaerobic biological sludge in an anaerobic state to perform anaerobic treatment to reduce the selenium compound.
At this time, the anaerobic treatment process is performed by using the biological sludge of the independent biota so that the biological sludge of one anaerobic treatment process does not move to the other anaerobic treatment process.

In order to prevent biological sludge in one anaerobic treatment step from moving to the other anaerobic treatment step, first and second solid-liquid separation steps are provided after the first and second anaerobic treatment steps, respectively. Solid-liquid separation in the first solid-liquid separation step, and anaerobically treating the separated liquid that was solid-liquid separated in the first solid-liquid separation step as water to be treated in the second anaerobic treatment step, and part of the separated sludge in the first solid-liquid separation step. Returned to the first anaerobic treatment step,
A method of returning a part of the separated sludge in the second solid-liquid separation step to the second anaerobic treatment step; a fixed type biological sludge such as biological filtration using a biofilm for the first and second anaerobic treatment steps. A method of anaerobic treatment using the same; a method of combining these methods can be mentioned.

By performing the anaerobic treatment while preventing the biological sludge from moving in this manner, each anaerobic treatment process is an independent biota, and the anaerobic treatment is performed by the biological sludge of different biota. Therefore, the removal of selenium can be enhanced. Anaerobic treatment with biological sludge of different biota, if necessary
A fourth ... Anaerobic treatment step can also be provided. The removal of selenium cannot be enhanced by simply performing anaerobic treatment in multiple stages under the condition that biological sludge moves. Therefore, a method in which solid-liquid separation is not performed in the first anaerobic treatment step and SS containing bacterial cells flows into the second anaerobic treatment step is not preferable. Note that a small amount of biological sludge is allowed to move, and for example, biological sludge up to about 10 to 20 mg / l as SS is allowed to be mixed into the water to be treated.

Specific anaerobic treatments in the first and second anaerobic treatment steps include denitrification, organic acid fermentation, sulfate reduction and the like, and the combination thereof is arbitrary. Specific combinations include 1) denitrification → organic acid fermentation (first anaerobic treatment step means denitrification step, second anaerobic treatment step means organic acid fermentation step), 2) organic acid fermentation → desorption Nitrogen, 3) denitrification → denitrification. Among these, the combination of 1) denitrification → organic acid fermentation is economical and preferable.

In the case of the combination of 1) above, in the first anaerobic treatment step, (nitrous) nitric acid and an organic substance are added to selenium-containing water (water to be treated) and denitrification is performed by denitrifying bacteria to reduce selenium. . In this case, the amount of the organic substance added is equal to or more than the amount required for denitrification, and the remaining organic substance may be subjected to organic acid fermentation in a subsequent organic acid fermentation process. It is desirable that the added amount of the organic substance is 4 to 20 times, preferably 6 to 10 times as much as NO ₃ -N as BOD. When the water to be treated already contains (nitro) nitric acid or an organic substance, it is not necessary to add them. Next, in the second anaerobic treatment step, the denitrification liquid denitrified in the first anaerobic treatment step, which is obtained by separating biological sludge by solid-liquid separation or biological filtration or the like, is treated with organic acid fermentation. Selenium is reduced by organic acid fermentation with bacteria.

In the case of the combination of the above 2), in the first anaerobic treatment step, an organic substance is added to selenium-containing water to perform organic acid fermentation to reduce selenium. Next, in the second anaerobic treatment step, an organic acid fermentation liquor obtained by performing organic acid fermentation in the first anaerobic treatment step, wherein the organic acid fermentation liquor obtained by separating biological sludge by solid-liquid separation or biological filtration, (Nitrous acid) is added and denitrification is performed by denitrifying bacteria to reduce selenium. In this case, the addition of (nitro) nitric acid is unnecessary in the first anaerobic treatment step, and the addition of organic substances is unnecessary in the second anaerobic treatment step.

In the case of the combination of the above 3), in the first anaerobic treatment step, (nitro) nitric acid and an organic substance are added to selenium-containing water and denitrification is performed by a denitrifying bacterium to reduce selenium. Next, in the second anaerobic treatment step, a denitrification liquid that has been denitrified in the first anaerobic treatment step and is a denitrification liquid obtained by separating biological sludge by solid-liquid separation or biological filtration,
(Nitrous acid) and organic substances are added to denitrify with denitrifying bacteria to reduce selenium. The organic substance is added in an amount not less than the amount required for denitrification in the first and second anaerobic treatment steps. In this case, both the first and second anaerobic treatment steps are denitrification steps, but the properties of the water to be treated, such as the redox potential,
Since the pH, water temperature, trace components, etc. are different, the biota of the two will be different even under the same conditions.

The biological sludge used in the first and second anaerobic treatment steps is a biological sludge produced by maintaining the selenium-containing water in an anaerobic state, and is used in the aerobic treatment method of wastewater such as the activated sludge treatment method. Biological sludge (activated sludge) can be collected, added to the water to be treated and maintained in an anaerobic state, so that it can be generated spontaneously. A bacterium that reduces (sub) selenic acid becomes dominant in such biological sludge, and such bacterium reduces (sub) selenic acid in selenium-containing water.

The biota produced in the biological sludge in the first and second anaerobic treatment steps differ depending on the composition of the water to be treated and the conditions of the anaerobic treatment. For example, in a system in which (nitrite) ions are present in the water to be treated, denitrifying bacteria that respire nitric acid become dominant. Further, acid-fermenting bacteria, hydrogen-producing bacteria, etc. appear in a system in which organic substances such as carbohydrates exist, and sulfate-reducing bacteria appear in a system in which sulfates exist. Depending on the substances present in other systems, bacteria suitable for decomposition appear,
Reduction of the selenium compound is carried out along with their decomposition.
In this way, separate biota are formed in the first and second anaerobic treatment steps.

The denitrifying bacteria that can be used in the first and second anaerobic treatment steps are bacteria that decompose organic matter by utilizing oxygen of (nitrite) ions by respiration of nitric acid, and among facultative anaerobic bacteria such as Pseudomonas. Seen in. Such denitrifying bacteria are used in the denitrification step in the denitrification method by nitrification denitrification utilizing the biological reaction of wastewater containing ammoniacal nitrogen. As the above-mentioned denitrifying bacterium, the denitrifying bacterium in such a biological denitrifying method can be used as it is, and aerobic sludge (activated sludge) in the aerobic treatment of wastewater such as the activated sludge treatment method is collected and used as an organic matter and It can also be generated spontaneously by maintaining it in an anaerobic state in the presence of (sub) nitrite.

The biological sludge containing such denitrifying bacteria and other bacteria for reducing (sub) selenic acid is usually a floc-like biological sludge, and in the present invention, the floc-like biological sludge is used as it is in a suspended state. However, it can also be used by supporting it on a granular, fibrous, or other carrier having a high porosity. The carrier is not limited as long as it can support biological sludge, and examples thereof include sand, activated carbon, alumina gel, and foamed plastic. The biological sludge can be carried on the carrier by acclimation or treatment in the presence of the carrier. In addition, a selenate-reducing bacterium may be fixed in a gel such as polyvinyl alcohol or polyethylene glycol.

In the first and second anaerobic treatment steps, the treatment
If the water is brought into contact with the biological sludge as described above in an anaerobic state,
And (se) selenic acid in the water to be treated, namely Se⁶⁺
And / or Se⁴⁺Is reduced and becomes insoluble. This and
Se⁶⁺Is Se⁴⁺Through Se ⁰And / or Se^2-To
It is estimated to be returned. First and second anaerobic treatment
Anaerobic state in the physical process means the state of blocking oxygen
However, it does not interfere with the reduction of selenium compounds.
Oxygen contamination is acceptable.

The first and second anaerobic treatment steps require an oxygen source and a nutrient source for respiration of biological sludge.
As an oxygen source, since it is in an anaerobic state, not oxygen in the molecular form but oxygen that can be an oxidant contained in the form of (nitro) nitrite, carbohydrate, organic acid, sulfuric acid, etc. is used. As a nutrient source, organic substances contained in the reaction liquid or organic sludge are used as substrates. These oxygen sources and nutrient sources can be used as they are if they are contained in the water to be treated, but if they are not contained, methanol or the like is added separately. As a result, the biological sludge is maintained at a high activity, and (s) selenic acid is reduced along with the decomposition thereof.

Explaining the case of biological sludge containing denitrifying bacteria, the presence of (nitrite) nitrate ion in the reaction system causes the denitrifying bacteria to appear in the biological sludge and keeps the activity high. Reduces selenate. When the (nitrite) nitrate ion is already present in the reaction system, it can be used as it is, but when it is not present, a (nitrite) salt or the like can be added. The (nitrite) nitrate may be added at a limit (about 1 to 10 mg / l as NOx) that maintains the activity of denitrifying bacteria.

When the raw water contains organic or ammoniacal nitrogen, the raw water is previously contacted with nitrifying bacteria in the nitrification step and nitrification is carried out under aerobic conditions to convert organic or ammoniacal nitrogen into (nitrite) nitrogen. Then, the nitrification solution is brought into contact with biological sludge containing denitrifying bacteria under anaerobic conditions to perform denitrification, and at the same time, (sub) selenic acid is reduced. In this case, the selenium compound is (selenite) selenic acid in the nitrification step, but it is reduced in the denitrification step as the anaerobic treatment step.

The first and second anaerobic treatment steps are carried out by introducing water to be treated into the anaerobic treatment tank. An anaerobic treatment tank is used for the contact between the water to be treated and the biological sludge, and any method such as a floating method or a biofilm method can be adopted. The floating method is a method in which floc-like biological sludge containing denitrifying bacteria is stirred and brought into contact with each other in a floating state, and is performed in the same manner as the denitrifying step in the biological denitrifying method. The biofilm method is a method in which biological sludge is supported on a carrier to form a biofilm, and this is brought into contact with the water to be treated.Fixed bed type, fluidized bed type, upflow type, downflow type, etc. The same method as that used in the denitrification process can be adopted.

The total residence time in the first and second anaerobic treatment tanks is the time required for the reduction of the (selen) selenate ion, which is necessary for the decomposition of organic substances existing in the system. It can be regarded as time, and when denitrifying or the like is performed in the system, it can be 1.1 times or more of the time required for denitrifying or the like. The first and second anaerobic treatments have a predetermined sludge concentration (500 to 50,000) so that the residence time becomes the above.
mg / l, preferably 2000-20000 mg / l)
The reaction is maintained at.

When the selenium compound is reduced in the first and second anaerobic treatment steps, an insoluble selenium compound is produced and adsorbed on the biological sludge. The selenium compound adsorbed on the biological sludge is removed from the system by separating and discharging the biological sludge by solid-liquid separation.

Since the anaerobic treatment liquid taken out from the second anaerobic treatment step contains organic substances and other oxidizable substances added in excess, it is necessary to oxidize and decompose them. An aerobic treatment step can be provided after the second anaerobic treatment step. Examples of such an aerobic treatment step include an activated sludge treatment step for decomposing excess organic matter used as a substrate in the anaerobic treatment step.

As the biological sludge used in such an aerobic treatment process, ordinary activated sludge can be used, and it can be spontaneously generated by aeration of the liquid to be treated. The activated sludge produced in the treatment device can also be used as biological sludge. In the aerobic treatment step, organic matter and other oxidizable substances are oxidized by contacting the second anaerobic treatment liquid with such biological sludge in an aerobic state, that is, aerating. The treatment conditions are the same as those for normal activated sludge treatment.

When performing aerobic treatment, the aeration amount is limited so that the selenium compound insolubilized in the anaerobic treatment step is not re-eluted by the aerobic treatment, and the redox potential (ORP) in the aerobic treatment step is maintained at 160 mV or less. It is preferable to perform the treatment as described above. Here, ORP is a value with a silver / silver chloride electrode as a reference.

It is presumed that the reason why the selenium concentration in the treated water is lowered by the method of the present invention is that the biota are different in the first anaerobic treatment step and the second anaerobic treatment step. In this case, the reason why the treated water selenium concentration decreases when the biota is different is not clear, but it is said that the bacteria will have the ability to reduce low-concentration selenium by acclimatizing in the environment of low-concentration selenium. Conceivable.

[0031]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. 1 and 2 are system diagrams showing a processing apparatus according to an embodiment of the present invention.
Shows an example of separating biological sludge by solid-liquid separation, and FIG. 2 shows an example of using a fixed type biological sludge. In FIG. 1, 1
Is a first anaerobic treatment tank, 2 is a first solid-liquid separation tank, 3 is a second
The anaerobic treatment tank 4 is a second solid-liquid separation tank.

In the method shown in FIG. 1, raw water (water containing selenium) is introduced from the raw water channel 11 into the first anaerobic treatment tank 1 together with the return sludge from the first return sludge passage 12, and gently stirred by the stirrer 13. The selenium compound is reduced by mixing it with the biological sludge in the tank and performing anaerobic treatment. At this time, an organic substance such as methanol is introduced as a substrate from the first organic substance supply passage 14, and an oxygen source such as (nitrous) nitric acid is introduced from the first oxygen source supply passage 15. These do not need to be introduced when present in raw water.

When denitrifying bacteria are used as biological sludge, (nitrite) is introduced as an oxygen source, when sulfate reducing bacteria is used, sulfate is introduced, and when acid-producing bacteria are used, these are unnecessary. Therefore, the organic substances in the raw water are used as they are. In the first anaerobic treatment tank 1, oxygen of the selenium compound is also used when breathing without using molecular oxygen, such as nitric acid breathing, by utilizing these oxygen sources, and the selenium compound is reduced and insolubilized.

Selenium insolubilized in the first anaerobic treatment tank 1 is adsorbed by biological sludge to form sludge. The in-tank liquid containing such sludge is extracted from the transfer path 16 to the first solid-liquid separation tank 2 and is separated into the solid-liquid there. Part of the separated sludge is returned to the first anaerobic treatment tank 1 from the first return sludge passage 12,
The rest is discharged as excess sludge from the first sludge passage 17.

The separated liquid separated in the first solid-liquid separation tank 2 is introduced into the second anaerobic treatment tank 3 as the water to be treated into the second anaerobic treatment tank 3 and the return sludge from the second return sludge passage 22 is introduced. Then, the mixture is gently stirred by the stirrer 23, mixed with the biological sludge in the tank, and subjected to anaerobic treatment to reduce the selenium compound.
At this time, an organic substance such as methanol is introduced as a substrate from the second organic substance supply passage 24, and the second oxygen source supply passage 25
Introduce an oxygen source such as (nitro) nitric acid. When the water to be treated contains an organic substance or when the organic substance is excessively introduced from the first organic substance supply passage 14, the addition of the organic substance is unnecessary. In addition, it is not always necessary to introduce the oxygen source from the second oxygen source supply passage 25, and it is not necessary to add the oxygen source particularly when performing organic acid fermentation. In the second anaerobic treatment tank 3, the selenium compound is reduced and insolubilized by the biota different from the first anaerobic treatment tank 1.

The selenium insolubilized in the second anaerobic treatment tank 3 is adsorbed by the biological sludge to form sludge. The in-tank liquid containing such sludge is extracted from the transfer path 26 to the second solid-liquid separation tank 4, and is separated into solid-liquid there. Part of the separated sludge is returned to the second anaerobic treatment tank 3 from the second return sludge passage 22,
The remaining part is discharged as excess sludge from the second sludge passage 27.
The separated liquid is discharged from the treated water channel 28 as treated water.

The selenium compound reduced and insolubilized in the first and second anaerobic treatment tanks 1 and 3 in this manner is
And, it is separated as solid matter in the second solid-liquid separation tanks 2 and 4, and a part thereof is discharged as excess sludge.

In FIG. 1, between the second anaerobic treatment tank 3 and the second solid-liquid separation tank 4, or after the second solid-liquid separation tank 4,
An aerobic treatment tank can be provided, and organic substances and other oxidizable substances remaining here can be oxidized and decomposed.
When an aerobic treatment tank is provided between the second anaerobic treatment tank 3 and the second solid-liquid separation tank 4 to perform aerobic treatment, the oxidation-reduction potential is 16
By aerating so as to be 0 mV or less, elution due to the oxidation of selenium can be prevented.

FIG. 2 shows an example in which a fixed type biological sludge is used. The first biological filtration layer 3 is provided in the first anaerobic treatment tank 1.
In the 1st, 2nd anaerobic treatment tank 3, the 2nd biological filtration layer 32 is formed by the different biota. In the method of FIG. 2, raw water (selenium-containing water) is supplied from the raw water channel 11 to the lower portion of the first anaerobic treatment tank 31. At this time, the first organic substance supply path 1
An organic substance such as methanol is supplied from 4 as a substrate, and an oxygen source such as (nitrous) nitric acid is supplied from the first oxygen source supply passage 15. These do not need to be supplied when present in raw water.

The selenium-containing water containing the organic matter and the oxygen source is anaerobically treated by passing water through the first biological filtration layer 31 in an upward flow. As a result, the selenium compound is reduced and becomes insoluble.
The insolubilized selenium is adsorbed by the biological sludge forming the first biological filtration layer 31 and removed from the water to be treated.

The anaerobic treated water anaerobically treated in the first anaerobic treatment tank 1 is taken out from the upper portion of the first anaerobic treatment tank 1 and is supplied to the lower portion of the second anaerobic treatment tank 3 from the transfer path 33 as water to be treated. . At this time, an organic substance such as methanol is supplied from the second organic substance supply passage 24 as a substrate, and an oxygen source such as (nitrous) nitric acid is supplied from the second oxygen source supply passage 25. If the water to be treated contains organic substances or is excessively supplied from the first organic substance supply passage 14, the addition of organic substances is unnecessary. Further, it is not always necessary to supply the oxygen source from the second oxygen source supply passage 25, and it is not necessary to add the oxygen source particularly when performing organic acid fermentation.

The water to be treated is anaerobically treated by passing it through the second biological filtration layer 32 in an upward flow. As a result, the selenium compound is reduced and insolubilized by the biota different from the first anaerobic treatment tank 1, adsorbed on the biological sludge forming the second biological filtration layer 32, and removed from the water to be treated. Second anaerobic treatment tank 3
The anaerobic treated water that has been anaerobically treated in (1) is discharged as treated water from the treated water passage 28 connected to the upper part of the second anaerobic treatment tank 3.

Also in FIG. 2, an aerobic treatment tank can be provided after the second anaerobic treatment tank 3 to oxidize and decompose residual organic substances and other oxidizable substances.

[0044]

Embodiments of the present invention will be described below. Comparative Example 1 With the apparatus of FIG. 1, except that the first solid-liquid separation tank 2 was omitted, and the sludge separated from the second solid-liquid separation tank 4 was returned to the first anaerobic treatment tank 1, The synthetic wastewater was treated under the following conditions.

Synthetic waste water: Se ⁶⁺ ; 2 mg / l NO ₃ —N; 100 mg / l SO ₄ ²⁻ ; 5000 mg / l methanol; 500 mg / l First anaerobic treatment tank 1: volume; 2 liter MLSS; 2500-500 3000 mg / l Addition of organic matter; None Addition of oxygen source; None First solid-liquid separation tank 2: omitted

Second anaerobic treatment tank 3: Volume: 1 liter MLSS; 2500 to 3000 mg / l Addition of organic matter; None Addition of oxygen source; None Second solid-liquid separation tank 4: Volume; 2.5 liter Above As a result of treatment for 60 days under the conditions, Se of treated water after one month elapsed during the treatment period was 0.2 to 0.4 mg / l.

Example 1 The process of Comparative Example 1 was switched to the process of the apparatus shown in FIG. That is, the first solid-liquid separation tank 2 having a volume of 2.5 liters is provided, and a part of the sludge separated in the first solid-liquid separation tank 2 is returned to the first anaerobic treatment tank 1, and the second solid-liquid separation tank 2 is returned. A part of the separated sludge in the separation tank 4 was returned to the second anaerobic treatment tank 3. Note that NO ₃ —N was added to the second anaerobic treatment tank 3 so as to have a concentration of 50 mg / l. After the switching, the Se of the treated water gradually decreased and became 0.06 to 0.13 mg / l one month later. The outlet water of the first solid-liquid separation tank 2 has Se of 0.22 to 0.41 m.
g / l, TOC is 180-190 mg / l, NOx-N
Was below the detection limit.

Example 2 Following Example 2, NO ₃ -N in the second anaerobic treatment tank 3 was used.
Was stopped. As a result, the treated water S
The e remained low as 0.07-0.12 mg / l.

[0049]

The method for treating selenium-containing water according to the present invention comprises performing the anaerobic treatment step in multiple stages and preventing biological sludge in one anaerobic treatment step from moving to the other anaerobic treatment step. Since the process was performed anaerobically using biological sludge of independent biota, it is possible to stably and efficiently remove selenium compounds from selenium-containing water, thereby obtaining treated water of low selenium concentration. You can

[Brief description of the drawings]

FIG. 1 is a system diagram showing a processing apparatus according to an embodiment of the present invention.

FIG. 2 is a system diagram showing a processing apparatus according to another embodiment of the present invention.

[Explanation of symbols]

 1 1st anaerobic treatment tank 2 1st solid-liquid separation tank 3 2nd anaerobic treatment tank 4 2nd solid-liquid separation tank 11 Raw water channel 12 1st return sludge path 13, 23 Stirrer 14 1st organic substance supply Channel 15 First oxygen source supply channel 16, 21, 26, 33 Transfer channel 17 First drainage channel 22 Second return sludge channel 24 Second organic matter supply channel 25 Second oxygen source supply channel 27 Second Drainage channel 28 Treated water channel 31 First biological filtration layer 32 Second biological filtration layer

Claims (1)

[Claims] 1. A first anaerobic treatment step in which selenium-containing water is brought into contact with biological sludge in an anaerobic state to reduce selenium, and treated water anaerobically treated in the first anaerobic treatment step is brought into contact with biological sludge in an anaerobic state. And a second anaerobic treatment step of reducing selenium to prevent the biological sludge of one anaerobic treatment step from moving to the other anaerobic treatment step, and each anaerobic treatment step is a biological sludge of an independent biota. A method for treating selenium-containing water, which comprises performing anaerobic treatment using water.