JP7398692B2 - Wastewater treatment method and wastewater treatment equipment - Google Patents

Description

The present invention relates to a wastewater treatment method and wastewater treatment equipment.

In the process of manufacturing stainless steel sheets at a steelworks, the surface of the stainless steel sheet may be acid-cleaned using nitric acid. The wastewater after cleaning contains nitrate nitrogen. Such wastewater is discharged into public sea areas after nitrate nitrogen is removed and purified to a predetermined water quality in a wastewater treatment facility within a steelworks, for example.

Examples of methods for removing nitrate nitrogen include biological treatment using activated sludge containing microorganisms.
For example, Patent Document 1 states, ``This method is characterized by denitrifying nitrate nitrogen and nitrite nitrogen in water to be treated containing high concentration of salt equivalent to the salinity of seawater by a group of microorganisms including sulfur-oxidizing bacteria. "A biological denitrification treatment method" ([Claim 1]).

JP2004-305980A

An object of the present invention is to provide a novel wastewater treatment method and wastewater treatment equipment.

As a result of extensive studies, the present inventors have found that the above object can be achieved by employing the following configuration, and have completed the present invention.

That is, the present invention provides the following [1] to [7].
[1] For wastewater with a nitrate nitrogen concentration of 5,000 mg/L or more, biological treatment is performed using activated sludge containing anaerobic microorganisms to reduce the nitrate nitrogen concentration to 1,000 mg/L or less. How to obtain treated water and treat wastewater.
[2] The activated sludge contains, as the anaerobic microorganisms, nitrate-reducing bacteria belonging to the genus Sulfuricella of the family Gallionellaceae, and Hyphomicrobium of the family Hyphomicrobiaceae. Nitrate-reducing bacteria belonging to the genus Pelagibacterium in the family Hyphomicrobiaceae mentioned above, and bacteria belonging to the genus Plastorhodobacter in the family Rhodobacteraceae. nitrate-reducing bacteria, bacteria belonging to the Jhaorihella genus in the Rhodobacteraceae family, bacteria belonging to the Fontibacter genus in the Cyclobacteriaceae family, and Acholeplasmataceae. Bacteria belonging to the genus Acholeplasma in the family Flavobacteriaceae, bacteria belonging to the genus Altibacter in the family Flavobacteriaceae, and Ulvibacter in the family Flavobacteriaceae mentioned above. Bacteria belonging to the genus Aliidiomarina in the family Idiomarinaceae, bacteria belonging to the genus Halomonas in the family Halomonadaceae, Azoarcus in the family Zoogloeaceae Parabacteroides distasonis, a nitrate-reducing bacterium belonging to the genus Tannerellaceae, and Aquimonas, a new genus of bacteria belonging to the family Rhodanobacteraceae, which is 87% homologous to Parabacteroides distasonis, a member of the family Tannerellaceae. The wastewater according to [1] above, containing at least one type of bacteria selected from the group consisting of bacteria belonging to the genus Alkaliflexus in the family Marinilabiliaceae, and bacteria belonging to the genus Alkaliflexus in the family Marinilabiliaceae. processing method.
[3] Nitrate-reducing bacteria belonging to the genus Sulfuricella in the family Gallionellaceae are microorganisms with 98% homology to Sulfuricella denitrificans, and Hyphomicrobium nitrativorans is a nitrate-reducing bacterium belonging to the genus Hyphomicrobium of the family E), and Pelagibacterium of the family Hyphomicrobiaceae mentioned above. Bacteria belonging to the genus Pelagibacterium luteolum are 99% homologous to Pelagibacterium luteolum, and are nitrate-reducing bacteria belonging to the genus Plastorhodobacter in the family Rhodobacteraceae mentioned above. is a microorganism with 99% homology to Plastorhodobacter daqingensis, and bacteria belonging to the genus Jhaorihella in the family Rhodobacteraceae mentioned above are homologous to Jhaorihella thermophila. Fontibacter ferrireducens is a microorganism with a 95% sex ratio and belongs to the genus Fontibacter in the family Cyclobacteriaceae, and the Acholeplasmataceae Bacteria belonging to the genus Acholeplasma in the family Taceae are microorganisms that have 95% homology to Acholeplasma parvum, and the genus Altibacter in the family Flavobacteriaceae mentioned above. Bacteria belonging to the genus Ulvibacter in the family Flavobacteriaceae are microorganisms with 96% homology to Altibacter lentus, and bacteria belonging to the genus Ulvibacter in the family Flavobacteriaceae are called Ulvibacter antarcticus. ), and the nitrate-reducing bacterium belonging to the genus Aliidiomarina in the family Idiomarinaceae mentioned above has 99% homology to Aliidiomarina taiwanensis. Halomonas salifodinae is a microorganism that belongs to the genus Halomonas in the family Halomonadaceae, and is a nitrate-reducing bacterium that belongs to the genus Azoarcus in the family Zoogloeaceae. The bacterium is a microorganism with 97% homology to Azoarcus indigens or a microorganism with 99% homology to Azoarcus aromaticum, and is Parabacteroides distasonis of the family Tannerellaceae. A new genus of microorganisms that has 87% homology to Parabacteroides distasonis belongs to a new genus of microorganisms that has 87% homology to Parabacteroides distasonis, and a new genus that includes microorganisms that have 87% homology to Parabacteroides distasonis. Bacteria belonging to the genus Alkaliflexus in the family Marinilabiliaceae are microorganisms that have 99% homology to Aquimonas voraii, and bacteria belonging to the genus Alkaliflexus in the family Marinilabiliaceae mentioned above are microorganisms that have 99% homology to Aquimonas voraii. The method for treating wastewater according to [2] above, wherein the microorganism has 98% homology to (Lexus imschenecki).
[4] The activated sludge contains nitrate-reducing bacteria belonging to the genus Hyphomicrobium of the family Hyphomicrobiaceae as the anaerobic microorganisms, and the activated sludge contains The amount of nitrate-reducing bacteria belonging to the genus Hyphomicrobium of the family Hyphomicrobiaceae is 20% or more of the total amount of the anaerobic microorganisms contained in the activated sludge. , the method for treating wastewater according to [2] or [3] above.
[5] The activated sludge contains nitrate-reducing bacteria belonging to the genus Hyphomicrobium of the family Hyphomicrobiaceae as the anaerobic microorganisms, and the activated sludge contains The amount of nitrate-reducing bacteria belonging to the genus Hyphomicrobium of the family Hyphomicrobiaceae is 50% or more of the total amount of the anaerobic microorganisms contained in the activated sludge. , the method for treating wastewater according to any one of [2] to [4] above.
[6] Wastewater with a nitrate nitrogen concentration of 5,000 mg/L or more is subjected to biological treatment using activated sludge containing anaerobic microorganisms while a hydrogen donor is supplied. A wastewater treatment facility that obtains treated water with a concentration of 1,000 mg/L or less, comprising a treatment tank that retains the activated sludge inside, and a wastewater supply unit that supplies the wastewater to the inside of the treatment tank. A wastewater treatment facility comprising: a hydrogen donor supply section that supplies a hydrogen donor into the treatment tank; and a discharge section that discharges the obtained treated water to the outside of the treatment tank.
[7] The activated sludge contains, as the anaerobic microorganisms, nitrate-reducing bacteria belonging to the genus Sulfuricella of the family Gallionellaceae, and Hyphomicrobium of the family Hyphomicrobiaceae. Nitrate-reducing bacteria belonging to the genus Pelagibacterium in the family Hyphomicrobiaceae mentioned above, and bacteria belonging to the genus Plastorhodobacter in the family Rhodobacteraceae. nitrate-reducing bacteria, bacteria belonging to the Jhaorihella genus in the Rhodobacteraceae family, bacteria belonging to the Fontibacter genus in the Cyclobacteriaceae family, and Acholeplasmataceae. Bacteria belonging to the genus Acholeplasma in the family Flavobacteriaceae, bacteria belonging to the genus Altibacter in the family Flavobacteriaceae, and Ulvibacter in the family Flavobacteriaceae mentioned above. Bacteria belonging to the genus Aliidiomarina in the family Idiomarinaceae, bacteria belonging to the genus Halomonas in the family Halomonadaceae, Azoarcus in the family Zoogloeaceae Parabacteroides distasonis, a nitrate-reducing bacterium belonging to the genus Tannerellaceae, and Aquimonas, a new genus of bacteria belonging to the family Rhodanobacteraceae, which is 87% homologous to Parabacteroides distasonis, a member of the family Tannerellaceae. The wastewater according to [6] above, containing at least one type of bacteria selected from the group consisting of bacteria belonging to the genus Alkaliflexus in the family Marinilabiliaceae, and bacteria belonging to the genus Alkaliflexus in the family Marinilabiliaceae. processing equipment.

According to the present invention, a novel wastewater treatment method and wastewater treatment equipment can be provided.

It is a schematic diagram showing an anaerobic membrane separation activated sludge apparatus. It is a graph showing changes in the concentration of nitrate nitrogen (N concentration) and the relative abundance of specific microorganisms during a biological treatment test.

An embodiment of the present invention will be described below based on FIG. However, the present invention is not limited to the embodiments described below.

FIG. 1 is a schematic diagram showing an anaerobic membrane separation activated sludge apparatus 10 as wastewater treatment equipment. Hereinafter, the anaerobic membrane separation activated sludge device 10 will also be simply referred to as the "device 10." The device 10 is entirely covered to prevent air from entering the interior of the device 10.
As shown in FIG. 1, the apparatus 10 has a reaction tank 3 and a membrane separation tank 8 arranged in parallel. The reaction tank 3 and the membrane separation tank 8 communicate with each other through a communication pipe 17. The reaction tank 3 and the membrane separation tank 8 constitute a treatment tank that internally holds activated sludge 2, which will be described later.
A raw water inflow pipe 11 and an organic substance inflow pipe 12 are inserted into an inflow port 21 provided at the upper part of the reaction tank 3 . An inert gas discharge pipe 14 and a membrane-treated water discharge pipe 25 are inserted into an outlet 22 provided at the top of the membrane separation tank 8 . A return pipe 15 is inserted into the inlet 21 and the outlet 22 to communicate the reaction tank 3 and the membrane separation tank 8.
An inert gas supply device 4 is connected to the lower part of the reaction tank 3 via a bubbling pipe 5 and a diffuser pipe 6. An inert gas supply device 4 is connected to the lower part of the membrane separation tank 8 via a membrane cleaning pipe 7 and an aeration pipe 6.
A membrane module 9 is arranged inside the membrane separation tank 8 .

There may be two or more reaction tanks and two or more membrane separation tanks. In that case, communication is provided between the plurality of reaction vessels, between the reaction vessel and the membrane separation vessel, and between the plurality of membrane separation vessels through the communication pipe.

In such a configuration, in the reaction tank 3 of the device 10, biological treatment is performed on wastewater containing nitrate nitrogen (also referred to as "raw water") using the activated sludge 2 containing anaerobic microorganisms. . The activated sludge 2 preferably contains nitrate-reducing bacteria as the anaerobic microorganisms.

The concentration of nitrate nitrogen (NO ₃ -N) in raw water is 5,000 mg/L or more. The upper limit is not particularly limited, but is, for example, 10,000 mg/L or less, preferably 8,000 mg/L or less.
Examples of such raw water include waste water after cleaning the surface of a stainless steel plate using nitric acid.

The concentration of nitrate nitrogen (NO ₃ -N) in the present invention also includes the concentration of nitrite nitrogen (NO ₂ -N) converted into nitrate nitrogen.
First, the concentration of nitrate nitrogen (c3) is measured by the ion chromatography method specified in JIS K 0102 43.2.5. Separately, the concentration of nitrite nitrogen (c2) is measured by naphthaleneethylenediamine spectrophotometry specified in 43.1.1 of JIS K 0102. The measured concentration of nitrite nitrogen (c2) is converted to the concentration of nitrate nitrogen (c3'). The converted nitrate nitrogen concentration (c3') is added to the separately measured nitrate nitrogen concentration (c3) (c3+c3'). In this way, the concentration of nitrate nitrogen in the present invention is determined.

Since the waste water immediately after cleaning the surface of the stainless steel plate with nitric acid is acidic, it is preferable to neutralize it. For example, slaked lime (calcium hydroxide) is used for neutralization. In this case, the waste water after neutralization contains calcium. Therefore, it is preferable to pre-treat the neutralized wastewater to remove calcium using, for example, the soda lime method. The wastewater after such pretreatment contains sodium.

When the pretreated wastewater is used as raw water for biological treatment, its pH is preferably 4 to 10.

Raw water is supplied into the reaction tank 3 via the raw water inflow pipe 11 provided at the inlet 21 at the upper part of the reaction tank 3 . At this time, an organic substance such as methanol that serves as a hydrogen donor is also supplied into the reaction tank 3 via the organic substance inflow pipe 12 . The raw water inflow pipe 11 and the organic matter inflow pipe 12 constitute a wastewater supply section and a hydrogen donor supply section, respectively. Other additives such as phosphoric acid may also be supplied inside the reaction vessel 3.

Activated sludge 2 is introduced into the reaction tank 3 . It is preferable to analyze the microorganisms (anaerobic microorganisms) contained in the activated sludge 2 at an appropriate timing during the biological treatment.

For the analysis of microorganisms, it is preferable to use a high-performance sequencer called a "next generation sequencer." By using a next-generation sequencer, it is possible to identify microorganisms and search for their homology in large numbers at once in a short time, and it is possible to detect base sequences listed in the sequence listing. Examples of such next-generation sequencers include MiSeq manufactured by Illumina.
However, to obtain more accurate and detailed phylogenetic information, it is preferable to use a PC and analysis software. Examples of the analysis software include various software described in [Examples] below.

Activated sludge 2 contains anaerobic microorganisms,
(1) Nitrate-reducing bacteria belonging to the genus Sulfuricella in the family Gallionellaceae;
(2a) Nitrate-reducing bacteria belonging to the genus Hyphomicrobium in the family Hyphomicrobiaceae, and (2b) Pelagibacterium in the family Hyphomicrobiaceae. Bacteria belonging to the genus Um),
(3a) nitrate-reducing bacteria belonging to the genus Plastorhodobacter in the family Rhodobacteraceae; and (3b) bacteria belonging to the genus Jhaorihella in the family Rhodobacteraceae;
(4) Bacteria belonging to the Fontibacter genus of the Cyclobacteriaceae family,
(5) Bacteria belonging to the genus Acholeplasma in the family Acholeplasmataceae,
(6a) Bacteria belonging to the genus Altibacter in the family Flavobacteriaceae, and (6b) bacteria belonging to the genus Ulvibacter in the family Flavobacteriaceae.
(7) Nitrate-reducing bacteria belonging to the genus Aliidiomarina in the family Idiomarinaceae;
(8) Bacteria belonging to the genus Halomonas in the family Halomonadaceae,
(9) Nitrate-reducing bacteria belonging to the genus Azoarcus in the family Zoogloeaceae;
(10) Bacteria belonging to a new genus to which microorganisms with 87% homology to Parabacteroides distasonis of the family Tannerellaceae belong;
(11) Bacteria belonging to the genus Aquimonas of the family Rhodanobacteraceae, and
(12) It is preferable to contain at least one type of bacteria selected from the group consisting of bacteria belonging to the genus Alkaliflexus of the family Marinilabiliaceae.

Activated sludge 2 contains anaerobic microorganisms such as (1) nitrate-reducing bacteria belonging to the genus Sulfuricella of the family Gallionellaceae, and (2a) Hyphomicrobium of the family Hyphomicrobiaceae. It is more preferable to contain at least one type of bacteria selected from the group consisting of nitrate-reducing bacteria belonging to the genus Microbium.

(1) As the nitrate-reducing bacteria belonging to the genus Sulfuricella of the family Gallionellaceae, a microorganism (SEQ ID NO: 2) with 98% similarity to Sulfuricella denitrificans is preferable.

(2a) As the nitrate-reducing bacterium belonging to the genus Hyphomicrobium in the family Hyphomicrobiaceae, Hyphomicrobium nitrativorans (SEQ ID NO: 1) is preferred.
(2b) As a bacterium belonging to the genus Pelagibacterium in the family Hyphomicrobiaceae, there is a microorganism with 99% homology to Pelagibacterium luteolum (SEQ ID NO: 7). is preferred.

(3a) As the nitrate-reducing bacteria belonging to the genus Plastorhodobacter of the Rhodobacteraceae family, a microorganism (SEQ ID NO: 3) with 99% homology to Plastorhodobacter daqingensis is preferable. .
(3b) As the bacteria belonging to the genus Jhaorihella of the Rhodobacteraceae family, a microorganism (SEQ ID NO: 15) having 95% homology to Jhaorihella thermophila is preferred.

(4) As the bacterium belonging to the genus Fontibacter in the family Cyclobacteriaceae, Fontibacter ferrireducens (SEQ ID NO: 4) is preferable.

(5) As a bacterium belonging to the genus Acholeplasma of the family Acholeplasmataceae, a microorganism (SEQ ID NO: 5) having 95% homology to Acholeplasma parvum is preferred.

(6a) As the bacteria belonging to the genus Altibacter in the family Flavobacteriaceae, a microorganism (SEQ ID NO: 6) having 96% homology to Altibacter lentus is preferred.
(6b) As a bacterium belonging to the genus Ulvibacter of the family Flavobacteriaceae, a microorganism (SEQ ID NO: 9) having 96% homology to Ulvibacter antarcticus is preferred.

(7) As a nitrate-reducing bacterium belonging to the genus Aliidiomarina in the family Idiomarinaceae, a microorganism (SEQ ID NO: 8) with 99% homology to Aliidiomarina taiwanensis is preferable. .

(8) As the bacterium belonging to the genus Halomonas in the family Halomonadaceae, Halomonas salifodinae (SEQ ID NO: 10) is preferred.

(9) Nitrate-reducing bacteria belonging to the genus Azoarcus in the Zoogloeaceae family include microorganisms with 97% homology to Azoarcus indigens (SEQ ID NO: 11) or Azoarcus aromaticum. A microorganism with 99% homology (SEQ ID NO: 12) is preferred.

(10) A new genus of bacteria that includes a microorganism with 87% homology to Parabacteroides distasonis of the Tannerellaceae family includes a microorganism with 87% homology to Parabacteroides distasonis ( SEQ ID NO: 13) is preferred.

(11) As a bacterium belonging to the genus Aquimonas of the family Rhodanobacteraceae, a microorganism (SEQ ID NO: 16) having 99% homology to Aquimonas voraii is preferable.

(12) As a bacterium belonging to the genus Alkaliflexus in the family Marinilabiliaceae, a microorganism (SEQ ID NO: 14) having 98% homology to Alkaliflexus imshenetskii is preferred.

The amount of nitrate-reducing bacteria belonging to the genus Hyphomicrobium in the family Hyphomicrobiaceae (2a) contained in activated sludge 2 is the total amount of anaerobic microorganisms contained in activated sludge 2. 20% or more is preferable, and 50% or more is more preferable. This "%" means the relative abundance of 16S rRNA gene.

Inert gas is supplied to the reaction tank 3 from an inert gas supply device 4 via an aeration pipe 6 and a bubbling pipe 5. The inert gas is supplied from the lower part of the reaction tank 3 in a bubbling manner. The amount of inert gas supplied is not particularly limited, but is, for example, 5 to 10 L/min for the capacity of the reaction tank 3 of 10 L.

In the reaction tank 3, an oxygen-free anaerobic state is maintained by the supplied inert gas, and raw water, activated sludge 2, etc. are stirred. In this way, biological treatment (denitrification treatment) is performed on the raw water containing nitrate nitrogen, and treated water is obtained.
More specifically, nitrate nitrogen contained in raw water is decomposed by anaerobic microorganisms contained in activated sludge 2 with the addition of organic matter such as methanol that serves as a hydrogen donor, and nitrogen gas (N ₂ ), Carbon dioxide (CO ₂ ), water (H ₂ O), etc. are generated.

The concentration of nitrate nitrogen (NO ₃ -N) in treated water obtained by biological treatment can be reduced by continuing stable operating conditions, and specifically, can be reduced to 1,000 mg/L or less. If the anaerobic microorganisms contained in activated sludge are sufficiently acclimated, the concentration can be reduced to 300 mg/L or less.
When discharging treated water from a factory such as a steel mill, it is necessary to comply with wastewater standards that are permissible in the area where the factory is located. According to the present invention, the concentration of nitrate nitrogen (NO ₃ -N) in treated water can be reduced to a concentration that satisfies this wastewater standard.

The obtained treated water is transferred from the reaction tank 3 to the membrane separation tank 8 via the communication pipe 17 and passes through the membrane module 9. The treated water is subjected to solid-liquid separation by the membrane module 9, and membrane-treated water in which the activated sludge 2 is membrane-separated is obtained. The obtained membrane-treated water flows out of the apparatus 10 from a membrane-treated water outflow pipe 25 provided at the outlet 22 at the upper part of the membrane separation tank 8 .

The activated sludge 2 membrane-separated in the membrane module 9 is returned from the membrane separation tank 8 to the reaction tank 3 via the return pipe 15 as return sludge. A portion of the returned sludge may be sent to a sludge storage tank (not shown), and the portion in which microorganisms have been killed may be discarded. Additional activated sludge may be added.

Inert gas is supplied to the membrane module 9 of the membrane separation tank 8 from the inert gas supply device 4 via the aeration pipe 6 and the membrane cleaning pipe 7. The supplied inert gas maintains the membrane separation tank 8 containing the membrane module 9 in an anaerobic state.
The membrane surface of the membrane module 9 is cleaned with an inert gas and kept clear. At this time, the inert gas is preferably injected parallel to the membrane surface of the membrane module 9.
The inert gas is preferably supplied at a rate of 10 L/min or more to an effective membrane area of 0.012 m ² of the membrane module 9. The supply of inert gas for membrane cleaning can be carried out intermittently.

The inert gas supplied to the device 10 maintains the entire enclosed interior of the device 10 in an anaerobic condition. Excess inert gas is exhausted to the outside of the device 10 via the inert gas exhaust pipe 14.

The inert gas supplied to the device 10 is not particularly limited as long as it is a gas that does not contain oxygen and does not harm bacteria, and examples include gases such as nitrogen, argon, and helium, and even mixtures thereof. good.
Among these, high purity nitrogen gas is preferred as the inert gas, and its oxygen concentration is preferably less than 10,000 ppm (1 volume %), more preferably less than 1,000 ppm (0.1 volume %). Such high-purity nitrogen gas is obtained from air using methods such as cryogenic separation, PSA separation, and membrane separation.
In particular, the cryogenic separation method is suitable because it can generate a large amount of highly pure nitrogen gas with an oxygen concentration of 100 ppm (0.01 volume %) or less. Gas production equipment that uses the cryogenic separation method is used in factories such as steel mills that require large amounts of oxygen gas for refining, and generates large amounts of high-purity nitrogen gas as a byproduct. Nitrogen gas, which is a byproduct of this process, may also be used.

The embodiment using the anaerobic membrane separation activated sludge apparatus 10 shown in FIG. 1 has been described above.
However, the present invention is not limited to the embodiments described above; for example, raw water is introduced into a sealed digestion tank filled with activated sludge, and biological treatment is performed by giving a predetermined hydraulic retention time (HRT). A method of settling waste sludge and obtaining the supernatant as treated water (standard digestion method); In the standard digestion method, a method of shortening HRT by agitating the inside of the digestion tank with mechanical stirring during biological treatment (high rate method) Digestion method); In the high-rate digestion method, sludge that has been precipitated and separated from treated water is returned to the digestion tank (anaerobic contact method); Raw water is passed through a treatment tank that holds a filler with activated sludge supported on its surface. Methods such as a method of forming a fluidized bed in which a carrier carrying activated sludge on the surface is fluidized in raw water (anaerobic fluidized bed method) may be applied.

The present invention will be specifically described below with reference to Examples. However, the present invention is not limited to these.

<Biological treatment test details>
A biological treatment test was conducted using the anaerobic membrane separation activated sludge apparatus 10 described based on FIG. As raw water to be subjected to biological treatment, wastewater was used after cleaning the surface of a stainless steel plate using nitric acid. The waste water after cleaning the stainless steel plate with nitric acid was neutralized with slaked lime. The pH of the wastewater after neutralization was 4-8. After neutralization using slaked lime, the wastewater was pretreated to remove calcium using the soda lime method. The pH of the wastewater after pretreatment was 9-10. The pretreated wastewater was used as raw water for biological treatment.
Nitrogen gas was used as the inert gas.

Other main conditions are as follows.
Concentration of nitrate nitrogen in raw water: 5,000 to 8,000 mg/L
Methanol injection amount: 12,000-18,000mg/L
Hydraulic residence time (HRT): 12 days Reactor capacity: 20L
Capacity of membrane separation tank: 6L
Raw water flow rate: 2.2L/day Sludge return rate: 13.0L/day Sludge extraction amount from reaction tank: 0.49L/day Water temperature: 22-25℃
pH in tank: 8.0-8.5

<Analysis of microorganisms>
During the biological treatment test, microorganisms contained in the activated sludge were analyzed every day. Specifically, the following procedure was performed using a next-generation sequencer.
First, a sludge sample (centrifugal sediment) of activated sludge was obtained by centrifugation. Mixed beads of zirconia and silica (Zirconia/Silica Beads) with an average particle diameter of 0.1 mm were added to the obtained sludge sample, and the mixture was subjected to a bead beater (Shake Master, manufactured by Biomedical Science Co., Ltd.) to remove sludge. Microbial cells contained in the sample were disrupted to obtain a cell disruption solution. From the obtained cell lysate, chromosomal DNA was extracted and purified by the phenol-chloroform extraction method.
Next, based on the universal primer targeting 16S rRNA of chromosomal DNA, the PCR (Polymerase Chain Reaction) method was performed using the primer described in Reference 1 below to which a barcode sequence for MiSeq manufactured by Illumina was added. The 16S rRNA gene was amplified.
Reference 1: J Gregory Caporaso et al., The ISME Journal (2012) 6, (1621-1624)

Unreacted primers and primer dimers were removed from the obtained PCR amplification product using AMPure magnetic beads (Beackmann Coulter, A63881) and a purification magnetic stand (Beackmann Coulter, A32782).
Next, the obtained purified product was fractionated by agarose gel electrophoresis, and only the PCR amplification product having the desired fragment length was isolated using a spin column (Promega, Wizard SV Gel and PCR Clean-up System). Purified.

Next, the DNA concentration in the DNA sample (chromosomal DNA) was measured using a fluorescent reagent kit for DNA staining, Quant-iT PicoGreen dsDNA Assay Kit (manufactured by Thermo Scientific, P11496) and a fluorescence spectrometer for trace amounts (manufactured by Thermo Scientific, NanoDrop 3300). It was quantified. The required amount was applied to MiSeq Reagent Kits v2 (manufactured by Illumina, MS-102-2001), and DNA sequence analysis was performed using a next-generation sequencer.

As a result, approximately 10,000 to 80,000 reads of sequence data were obtained from each DNA sample.
Gene sequence information was linked to the obtained sequence data using software ea-utils-1.1.2-301 (free software available on the Internet). Furthermore, chimeric sequences were removed using the software Mothur version 1.31.2 (see Reference 2 below for details). After that, we conducted a phylogenetic analysis of the gene sequence using the software QIIME version 1.6.0 (for details, see Reference 3 below), and examined the relationship between the relative abundance of each microbial species and physicochemical parameters. did.
Reference 2: Schloss PD et al., Appl. Environ. Microbiol (2009) 75, 7537-7541
Reference 3: Caporaso HG et al., Nat.methods (2012) 7, 335-336.

<Test results>
During the biological treatment test, the concentration of nitrate nitrogen (N concentration) in raw water and treated water was measured. Furthermore, as mentioned above, microorganisms contained in the activated sludge were analyzed.

Table 1 below shows the genus and species name (Bacteria), gene homology (identity) (unit: %), and relative abundance (unit: %) of the dominant bacterial species on the 41st day from the start of the test. ) is shown.

Table 2 below shows the genus and species name (Bacteria), gene homology (identity) (unit: %), and relative abundance (unit: %) of the dominant bacterial species 79 days after the start of the test. ) is shown.

FIG. 2 is a graph showing changes in the concentration of nitrate nitrogen (N concentration, unit: mg/L) and the relative abundance of specific microorganisms (unit: %) during the biological treatment test.

As shown in the graph of Figure 2, the concentration of nitrate nitrogen in the treated water was below 1,000 mg/L after about 34 days from the start of the test, and below 10 mg/L after about 82 days from the start of the test. became.

From the graph in Figure 2, it can be seen that a microbial environment suitable for biological treatment of raw water with a high concentration of nitrate nitrogen of 5,000 to 8,000 mg/L was achieved.
That is, as shown in the graph of Figure 2, first, a microorganism with 98% homology to Sulfuricella denitrificans (in the graph of Figure 2, for convenience, it is simply written as "Sulfuricella denitrificans"). The relative abundance of 100% of the total amount of 20% of the total amount of 20% of the total amount of 20% of the total amount increased, peaking approximately 13 days after the start of the test, and then decreasing.
As if to reverse this decline, the relative abundance of Hyphomicrobium nitrativorans, which was initially low, gradually increased, reaching more than 20% on the 32nd day from the start of the test, and approximately By the 75th day, it had become more than 50%.
It is speculated that microorganisms with 98% homology to Sulfuricella denitrificans and Hyphomicrobium nitrativorans increased at different times and played complementary roles in nitrate reduction. Ru.

2: Activated sludge 3: Reaction tank (treatment tank)
4: Inert gas supply device 5: Bubbling pipe 6: Diffusion pipe 7: Membrane cleaning pipe 8: Membrane separation tank (processing tank)
9: Membrane module 10: Anaerobic membrane separation activated sludge equipment (wastewater treatment equipment)
11: Raw water inflow pipe (drainage supply section)
12: Organic matter inflow pipe (hydrogen donor supply section)
14: Inert gas discharge pipe 15: Return pipe 17: Communication pipe 21: Inflow port 22: Outflow port 25: Membrane treated water outflow pipe

Claims (8)

Wastewater with a nitrate nitrogen concentration of 5,000 mg/L or more and 8,000 mg/L or less is subjected to biological treatment using activated sludge containing anaerobic microorganisms and methanol to reduce the nitrate nitrogen concentration to 1,000 mg/L or less. A wastewater treatment method for obtaining treated water of 000 mg/L or less,
The activated sludge contains, as the anaerobic microorganisms, nitrate-reducing bacteria belonging to the genus Sulfuricella in the family Gallionellaceae, and genus Hyphomicrobium in the family Hyphomicrobiaceae. A method for treating wastewater containing nitrate-reducing bacteria. The nitrate-reducing bacteria belonging to the genus Sulfuricella of the family Gallionellaceae is a microorganism with 98% homology to Sulfuricella denitrificans,
The wastewater treatment according to claim 1, wherein the nitrate-reducing bacterium belonging to the genus Hyphomicrobium of the family Hyphomicrobiaceae is Hyphomicrobium nitrativorans. Method. The activated sludge further contains, as the anaerobic microorganism,
Bacteria belonging to the Pelagibacterium genus of the Hyphomicrobiaceae family,
Nitrate-reducing bacteria belonging to the Plastorhodobacter genus of the Rhodobacteraceae family, and bacteria belonging to the Jhaorihella genus of the Rhodobacteraceae family,
Bacteria belonging to the Fontibacter genus in the Cyclobacteriaceae family,
Bacteria belonging to the genus Acholeplasma in the family Acholeplasmataceae,
Bacteria belonging to the genus Altibacter in the family Flavobacteriaceae, and bacteria belonging to the genus Ulvibacter in the family Flavobacteriaceae,
Nitrate-reducing bacteria belonging to the genus Aliidiomarina in the family Idiomarinaceae,
Bacteria belonging to the genus Halomonas in the family Halomonadaceae,
Nitrate-reducing bacteria belonging to the genus Azoarcus in the family Zoogloeaceae;
Bacteria belonging to a new genus containing microorganisms with 87% homology to Parabacteroides distasonis of the Tannerellaceae family;
Bacteria belonging to the genus Aquimonas of the family Rhodanobacteraceae, and
The method for treating wastewater according to claim 1 or 2, comprising at least one type of bacteria selected from the group consisting of bacteria belonging to the genus Alkaliflexus of the family Marinilabiliaceae. The bacterium belonging to the genus Pelagibacterium of the family Hyphomicrobiaceae is a microorganism with 99% homology to Pelagibacterium luteolum,
The nitrate-reducing bacteria belonging to the genus Plastorhodobacter of the Rhodobacteraceae family is a microorganism with 99% homology to Plastorhodobacter daqingensis,
The bacterium belonging to the genus Jhaorihella of the Rhodobacteraceae family is a microorganism with 95% homology to Jhaorihella thermophila,
The bacterium belonging to the Fontibacter genus of the Cyclobacteriaceae family is Fontibacter ferrireducens,
The bacterium belonging to the Acholeplasma genus of the Acholeplasmataceae family is a microorganism with 95% homology to Acholeplasma parvum,
The bacterium belonging to the genus Altibacter of the family Flavobacteriaceae is a microorganism with 96% homology to Altibacter lentus;
The bacterium belonging to the genus Ulvibacter of the family Flavobacteriaceae is a microorganism with 96% homology to Ulvibacter antarcticus,
The nitrate-reducing bacteria belonging to the genus Aliidiomarina of the family Idiomarinaceae is a microorganism with 99% homology to Aliidiomarina taiwanensis;
The bacterium belonging to the Halomonas genus of the Halomonadaceae family is Halomonas salifodinae,
The nitrate-reducing bacteria belonging to the genus Azoarcus of the Zoogloeaceae family is a microorganism with 97% homology to Azoarcus indigens or a microorganism with 99% homology to Azoarcus aromaticum. can be,
A bacterium belonging to a new genus to which a microorganism with 87% homology to Parabacteroides distasonis of the Tannerellaceae family belongs is a microorganism with 87% homology to Parabacteroides distasonis,
The bacterium belonging to the genus Aquimonas of the family Rhodanobacteraceae is a microorganism with 99% homology to Aquimonas voraii,
The waste water according to claim 3, wherein the bacteria belonging to the genus Alkaliflexus of the family Marinilabiliaceae are microorganisms having 98% homology to Alkaliflexus imshenetskii. Processing method. The amount of nitrate-reducing bacteria belonging to the Hyphomicrobium genus of the Hyphomicrobiaceae family contained in the activated sludge is relative to the total amount of the anaerobic microorganisms contained in the activated sludge. The method for treating wastewater according to any one of claims 1 to 4, wherein the amount of waste water is 20% or more. For wastewater with a nitrate nitrogen concentration of 5,000 mg/L or more and 8,000 mg/L or less, biological treatment is performed using activated sludge containing anaerobic microorganisms while a hydrogen donor is supplied, A wastewater treatment facility that obtains treated water with a nitrate nitrogen concentration of 1,000 mg/L or less,
a treatment tank that holds the activated sludge therein;
a wastewater supply unit that supplies the wastewater to the inside of the treatment tank;
a hydrogen donor supply unit that supplies methanol, which is a hydrogen donor, into the processing tank;
a discharge section that discharges the obtained treated water to the outside of the treatment tank;
The activated sludge contains, as the anaerobic microorganisms, nitrate-reducing bacteria belonging to the genus Sulfuricella in the family Gallionellaceae, and genus Hyphomicrobium in the family Hyphomicrobiaceae. Treatment equipment for wastewater containing nitrate-reducing bacteria belonging to The nitrate-reducing bacteria belonging to the genus Sulfuricella of the family Gallionellaceae is a microorganism with 98% homology to Sulfuricella denitrificans,
The wastewater treatment according to claim 6 , wherein the nitrate-reducing bacterium belonging to the genus Hyphomicrobium of the family Hyphomicrobiaceae is Hyphomicrobium nitrativorans. Facility. The activated sludge further contains, as the anaerobic microorganism,
Bacteria belonging to the Pelagibacterium genus of the Hyphomicrobiaceae family,
Nitrate-reducing bacteria belonging to the Plastorhodobacter genus of the Rhodobacteraceae family, and bacteria belonging to the Jhaorihella genus of the Rhodobacteraceae family,
Bacteria belonging to the Fontibacter genus in the Cyclobacteriaceae family,
Bacteria belonging to the genus Acholeplasma in the family Acholeplasmataceae,
Bacteria belonging to the genus Altibacter in the family Flavobacteriaceae, and bacteria belonging to the genus Ulvibacter in the family Flavobacteriaceae,
Nitrate-reducing bacteria belonging to the genus Aliidiomarina in the family Idiomarinaceae,
Bacteria belonging to the genus Halomonas in the family Halomonadaceae,
Nitrate-reducing bacteria belonging to the genus Azoarcus in the family Zoogloeaceae;
Bacteria belonging to a new genus containing microorganisms with 87% homology to Parabacteroides distasonis of the Tannerellaceae family;
Bacteria belonging to the genus Aquimonas of the family Rhodanobacteraceae, and
The wastewater treatment equipment according to claim 6 or 7 , comprising at least one type of bacteria selected from the group consisting of bacteria belonging to the genus Alkaliflexus of the family Marinilabiliaceae.