JPH09206780A - Aerobic biological treating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To keep the ozone concn. in the working environment low by providing a draft tube dividing a liq. in a biological reaction tank, supplying an ozone- contg. gas into the tube from the lower end side and collecting the waste gaseous ozone from the upper end side of the tube. SOLUTION: When an org. waste liq. is aerobically treated, the raw water is introduced into a biological treating tank 1 and mixed with a biological sludge, the air supplied from an air feed passage 6 is diffused from a diffuser 5 to conduct aerobic treatment, and the ozone treatment is performed simultanesouly in the reaction tank 1. Namely, the ozone-contg. gas is diffused into the draft tube 11 from the ozone-contg. gas feeder 16, the ozone-contg. gas ascending in the tube 11 is allowed to react with sludge, passed through an upper opening 12 and collected in the gas collecting part 22 of a hood. Further, the ozone-treated sludge is again aerobically treated, hence the sludge is reduced in volume, and scumming is prevented.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an aerobic biological treatment apparatus for treating a liquid in a biological reaction tank with ozone in the biological reaction tank.

[0002]

2. Description of the Related Art Aeration is carried out for the purpose of reducing the solubilization of excess sludge in activated sludge treatment, improving the sedimentation property of biological sludge (hereinafter sometimes simply referred to as sludge), and preventing the generation of scum in a solid-liquid separation tank. BACKGROUND ART Ozone treatment is performed by bringing a part of liquid or separated sludge into contact with ozone.

For example, JP-A-7-96299 and JP-A-7-96299.
No. 232184 describes an ozone treatment device that performs ozone treatment of separated sludge and aeration liquid in order to reduce the volume of excess sludge, but these ozone treatment devices are not called aeration tanks (biological reaction tanks). Since it is an independent device, it requires an installation area.

In PPM, "Technology of Actinomycete Scum Suppression by Addition of Ozone", 1995, No. 8, pp. 44-51, ozone is introduced into the aeration tank in order to prevent the generation of scum in the solid-liquid separation tank. However, a method of suppressing the generation of scum due to actinomycetes by contacting the liquid in the tank with ozone is described. However, in this method, in order to maintain the environmental ozone concentration in the work area at 0.1 volppm or less of the Ministry of Health and Welfare ozone equipment guidelines, it is necessary to make the entire aeration tank a completely sealed structure, which makes the equipment large and costly. Get high

[0005]

SUMMARY OF THE INVENTION An object of the present invention is to perform ozone treatment in a biological reaction tank, and to collect exhaust ozone with a simple structure without making the entire biological reaction tank completely sealed. Therefore, it is an object of the present invention to provide an aerobic biological treatment apparatus that can maintain the environmental ozone concentration in the work area at a low concentration and thereby can efficiently and inexpensively perform ozone treatment.

[0006]

The present invention is a biological reaction tank for mixing an organic waste liquid with biological sludge for aeration, and a cylindrical body for partitioning the liquid inside the biological reaction tank. A draft tube having an upper end opened near the liquid surface and a lower end opened in the liquid, an ozone-containing gas supply means for supplying an ozone-containing gas into the draft tube from the lower end side of the draft tube, and an upper end side of the draft tube. And a gas collecting means for collecting ozone exhaust gas from the aerobic biological treatment apparatus.

The organic effluent to be treated in the apparatus of the present invention is an effluent containing an organic substance treated by a usual aerobic biological treatment method, but contains an organic substance or an inorganic substance which is hardly biodegradable. It may have been done. Such organic effluents include sewage, night soil, food factory effluents and other industrial effluents.

The biological reaction tank in the apparatus of the present invention is a tank for receiving an organic waste liquid and optionally returned sludge, mixing with the biological sludge in the tank and aerating it to perform aerobic biological treatment. Therefore, an aeration means such as that provided in a normal biological reaction tank, for example, an air diffuser is installed in the tank.

The draft tube according to the present invention is a cylindrical body which is installed in the biological reaction tank to partition the liquid in the tank, and the upper end is opened near the liquid surface and the lower end is opened in the liquid. The upper end of the draft tube may be above or below the liquid surface, but it is preferable to open in the range of 20 to 100 cm below the liquid surface. Also, the lower end should be in the liquid,
It is preferable to open the lower part of the biological reaction tank, especially near the bottom surface, and it is more preferable to open it at a position about 20 to 50 cm from the bottom surface.

The draft tube is formed in a cylindrical shape or a prismatic shape, and the inside of the cylinder is hollow. The cavity is filled with the in-tank liquid of the biological reaction tank, and is divided by the wall of the draft tube into the in-tank liquid inside the hollow part (inside the draft tube) and the in-tank liquid outside the hollow part (outside the draft tube).
Thereby, by supplying the ozone-containing gas into the draft tube from the ozone-containing gas supply means described later,
The ozone treatment is performed in the draft tube. In this case, an ascending flow is generated in the draft tube, the liquid in the tank flows into the draft tube from the opening at the lower end, and flows out of the draft tube from the opening at the upper end, and the liquid in the tank circulates inside and outside the draft tube. The structure is as follows.

The ozone-containing gas supply means in the apparatus of the present invention is a means for supplying the ozone-containing gas into the draft tube from the lower end side of the draft tube, and the ozone-containing gas supply pipe may be opened as it is. It is preferable that the ozone-containing gas is finely divided and dispersed. As such, a perforated plate or a perforated tube provided with a large number of openings; a porous diffuser material formed of a porous material having a large number of fine holes (for example, a ceramic diffuser tube); as a submersible stirring pump A known mechanical air diffuser; a gas suction type air diffuser using an ejector can be adopted. The gas suction type air diffuser has one end opening into the biological reaction tank, a circulation pump and an ejector (the ejector has an ozone-containing gas intake port) in the middle, and the other end opening near the draft tube. The ozone-containing gas is supplied by circulating the in-tank liquid in the biological reaction tank through the circulation path.

The ozone-containing gas supply means is installed so that the ozone-containing gas can be introduced into the draft tube from the lower end side of the draft tube. For example, it can be provided in the vicinity of the lower portion in the draft tube, or can be provided below the lower end of the draft tube. It suffices if an upward flow is generated in the draft tube due to the gas lift effect.

As the ozone-containing gas, ozone-containing air,
Ozonized air can be used. The supply amount of ozone-containing gas and the ozone concentration can be arbitrarily set in consideration of the gas lift effect, the influence on microorganisms, and the amount of ozone-treated sludge.
For example, when all the microorganisms in the sludge are killed by contact with ozone, 1/3 of the liquid volume in the biological reaction tank
Hereafter, preferably, an amount of about 1/4 or less is circulated in the draft tube. Further, in the case where about half the amount of microorganisms is killed by contact with ozone, it is possible to circulate 2/3 or less of the liquid amount in the biological reaction tank. The amount of treatment passing through the draft tube can be adjusted by adjusting the amount of supply gas or the number of draft tubes installed.

The gas collecting means in the apparatus of the present invention is configured to collect ozone exhaust gas from the upper end side of the draft tube. As the gas collecting means, it is possible to use a means that can collect gas that rises in the draft tube and is released from the liquid surface to the atmosphere. As such a gas collecting means, an umbrella-shaped cover body which covers the opening at the upper end of the draft tube so as to cover it can be used. It is preferable that the diameter of the cover is slightly larger than the outer diameter of the draft tube, because ozone exhaust gas can be reliably collected.
Further, it is preferable to arrange the outer peripheral end of the cover lid so as to be submerged in the liquid surface of the biological reaction tank so that the ozone exhaust gas can be reliably collected, but it is not always necessary to submerge it. The cover may be fixed to the draft tube or reaction tank,
You may float it on the surface of the water. A gas outlet is provided on the top of the umbrella-shaped cover, and the collected ozone exhaust gas is taken out.

The extracted ozone exhaust gas can be introduced into an exhaust ozone treatment tower filled with an ozone decomposing material such as activated carbon or a manganese dioxide-supported catalyst to decompose the residual ozone, or can be recovered and reused. You can also

A plurality of draft tubes can be arranged and connected to a series, and by reusing ozone exhaust gas in one stage as ozone-containing gas in the next stage and thereafter,
Ozone can be effectively used. In this case, the exhaust gas taken out from the gas collecting means at a certain stage is configured to be supplied into the draft tube from the ozone containing gas supplying means at the next stage. By maximizing the use of ozone in this way, if the ozone concentration in the exhaust gas decreases,
By supplying the exhaust gas to the aerator for aeration, it can be absorbed into the activated sludge to be rendered harmless.

In the aerobic biological treatment apparatus of the present invention, in order to mix and aerate the liquid to be treated as activated sludge, an aeration device adopted for ordinary aerobic treatment is installed in the biological reaction tank, as well as the biological reaction. A solid-liquid separator is installed to separate the sludge and the treatment liquid from the reaction liquid in the tank.

In the aerobic biological treatment apparatus of the present invention, by supplying the ozone-containing gas into the draft tube from the ozone-containing gas supply means, the tank liquid containing sludge comes into contact with ozone in the draft tube, and the ozone treatment is performed. Done.
Further, due to the upward flow due to the gas lift effect, the liquid inside the draft tube circulates inside the tank, and the liquid inside the tank outside the draft tube flows in and undergoes ozone treatment and circulates. The gas that has risen in the draft tube is collected as ozone exhaust gas by the gas collection means, and is processed or reused.

The use efficiency of ozone increases as the bubbles generated become smaller and the water depth becomes deeper, and is about 70 to 90% at a water depth of 5 m using an ordinary ceramic air diffuser. By reusing the ozone exhaust gas as described above, the ozone utilization efficiency is increased.

Since the apparatus of the present invention is provided with the draft tube in the biological reaction tank, the installation area of the apparatus for ozone treatment is unnecessary. Moreover, ozone can be collected with a simple structure without making the entire biological reaction tank a closed structure, so that the cost is low and the environmental ozone concentration in the work area is low, for example, 0.1 vol, which is the ozone facility guideline of the Ministry of Health and Welfare.
It can be maintained below ppm.

By treating the organic effluent with aerobic organisms using the apparatus of the present invention, it is possible to reduce the volume of sludge and prevent the generation of scum. That is, since the activated sludge in the tank liquid is ozone-treated and a part of the sludge is killed by the ozone treatment described above, the dead sludge is assimilated to other living sludges, so that the sludge in the tank is The amount is reduced. Further, the ozone treatment kills actinomycetes and prevents the generation of floating scum in the solid-liquid separation tank.

Therefore, the aerobic biological treatment apparatus of the present invention is used not only for the purpose of reducing excess sludge but also for the purpose of preventing floating gas generation in the solid-liquid separation tank and for other purposes. can do.

[0023]

Embodiments of the present invention will now be described with reference to the drawings. FIG. 1 is a system diagram showing an aerobic biological treatment apparatus according to one embodiment of the present invention.

In FIG. 1, reference numeral 1 is a biological reaction tank, to which a raw water channel 2, a sludge returning channel 3 and a connecting channel 4 are connected.
An air diffuser 5 is provided near the bottom of the biological reaction tank 1,
The air supply path 6 is in communication. Further, a draft tube 11 is provided in the biological reaction tank 1, and an upper end opening 12 is opened below the liquid surface near the liquid surface, and a lower end opening 13 is opened near the bottom,
A gap 14 is formed between the lower end opening 13 and the bottom surface of the biological reaction tank 1.
Are formed.

An ozone-containing gas supply device 16 is provided at the lower end opening 13 and is connected to an ozone-containing gas supply path 17. The ozone-containing gas supply device 16 and the ozone-containing gas supply path 17 constitute ozone-containing gas supply means. An umbrella-shaped cover body 19 is provided on the upper portion of the draft tube 11 so as to cover the upper end opening portion 12, and an ozone exhaust gas extraction passage 20 is connected to the top portion. The diameter of the cover body 19 is slightly larger than the outer diameter of the draft tube 11, the outer peripheral end portion 21 is submerged in water, and a gas collecting portion 22 is formed above the water surface in the cover body 19. The cover body 19 is fixed so as to form a gap 23 between the cover body 19 and the draft tube 11. A plurality of draft tubes 11 can be provided.

Reference numeral 25 denotes an exhaust ozone treatment tower, in which an ozone decomposition layer 26 filled with activated carbon, a manganese dioxide-supported catalyst, etc. is formed, an ozone exhaust gas extraction passage 20 from a cover 19 is provided in the lower portion, and an ozone exhaust gas passage 20 is provided in the upper portion. The exhaust gas passage 27 is connected. Reference numeral 31 denotes a solid-liquid separation tank, which is connected to the communication path 4, the sludge return path 3, and the treated water path 32 from the biological reaction tank 1. 33 is a drainage path.

In the aerobic biological treatment of organic waste liquid by the apparatus of FIG. 1, raw water is first introduced from the raw water channel 2 into the biological treatment tank 1 and mixed with the biological sludge in the tank, and then supplied from the air supply channel 6. Air is diffused from the diffuser 5 to perform aerobic biological treatment. As a result, the organic matter is decomposed by the biooxidation reaction.

In parallel with the aerobic biological treatment, ozone treatment is carried out in the biological reaction tank 1. That is, the ozone-containing gas supplied from the ozone-containing gas supply path 17 is diffused from the ozone-containing gas supply device 16 into the draft tube 11. The ozone-containing gas rising in the draft tube 11 reacts with the sludge, passes through the upper end opening 12, and is collected by the gas collecting portion 22 of the cover body 19. As the ozone-containing gas rises, an upward flow is generated in the draft tube 11, and the liquid in the draft tube 11 flows out of the draft tube 11 through the upper end opening 12 and the gap 23, and the lower gap 14 and The liquid in the tank outside the draft tube 11 flows into the draft tube 11 through the lower end opening 13. By circulating the in-tank liquid in the draft tube 11 in this manner, the entire in-tank liquid is subjected to ozone treatment, and the ozone-treated sludge is again subjected to aerobic biological treatment. This makes it possible to reduce the volume of sludge and prevent the generation of scum.

The ozone exhaust gas collected in the gas collecting section 22 is taken out from the ozone exhaust gas taking-out passage 20 and introduced into the lower part of the exhaust ozone treating tower 25. While this ozone exhaust gas rises in the ozone decomposition layer 26, residual ozone is decomposed,
It is discharged from the exhaust gas passage 27.

The in-tank liquid in the biological reaction tank 1 is taken out part by part, introduced into the solid-liquid separation tank 31 through the communication path 4, and separated into the separated liquid and the separated sludge. The separated liquid is discharged as treated water from the treated water passage 32, and the separated sludge is returned to the biological reaction tank 1 from the sludge return passage 3 as return sludge. When excess sludge is generated, it is discharged from the sludge discharge path 33.

In the apparatus shown in FIG. 1, since the draft tube 11 is provided in the biological reaction tank 1 and the ozone treatment is carried out in the draft tube 11, the installation area of the apparatus for ozone treatment is unnecessary. Further, since the ozone exhaust gas can be collected with a simple structure without making the entire biological reaction tank 1 a closed structure, the cost is low and the environmental ozone concentration in the work area can be kept low.

[0032]

【Example】

Example 1 Wastewater from a food factory was subjected to aerobic biological treatment under the following conditions using the apparatus shown in FIG. Bioreactor 1 volume: 100 m ³ Draft tube 11 diameter: 50 cm Draft tube 11 length: 450 cm Ozone-containing gas ozone concentration: 20 g / m ³ Ozone-containing gas blow rate: 2 m ³ / hr Ozone decomposition layer 26: Activated carbon

The ozone concentration in the exhaust gas discharged from the gas collecting section 22 and the exhaust gas passage 27 was as follows. Gas collection unit 22: 3 g / m ³ (about 1400 volpp
m) Exhaust gas passage 27: 0 g / m ³ (0.1 volppm or less)

Comparative Example 1 In the apparatus shown in FIG.
Was installed, and aerobic biological treatment was performed in the same manner as in Example 1. As a result, ozone odor was generated in the upper part of the biological reaction tank 1, and 1 to 5 volppm of ozone was detected in the ozone measuring device provided directly above the water surface of the aeration tank in the ozone gas diffusing section.

[0035]

EFFECT OF THE INVENTION The aerobic biological treatment apparatus of the present invention is provided with a draft tube in the biological reaction tank and is configured to perform ozone treatment in the draft tube. The ozone treatment equipment has a small installation area, and the exhaust biological ozone is collected with a simple structure to maintain a low environmental ozone concentration in the work area without making the entire biological reaction tank completely sealed. You can
This makes it possible to efficiently and inexpensively perform ozone treatment.

[Brief description of drawings]

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

[Explanation of symbols]

 1 Biological Reaction Tank 2 Raw Water Channel 3 Sludge Return Channel 4 Connecting Channel 5 Air Diffuser 6 Air Supply Channel 11 Draft Tube 12 Upper End Opening 13 Lower End Opening 14, 23 Gap 16 Ozone-containing Gas Supply 17 17 Ozone-containing Gas Supply 19 Cover 20 Ozone exhaust gas extraction passage 21 Outer peripheral edge 22 Gas collection portion 25 Exhaust ozone treatment tower 26 Ozone decomposition layer 27 Exhaust gas passage 31 Solid-liquid separation tank 32 Treatment water passage 33 Waste mud passage

Claims (1)

[Claims] 1. A bioreaction tank for mixing an organic effluent with biological sludge to aerate, and a cylindrical body for partitioning the in-tank liquid in the bioreaction tank,
A draft tube having an upper end opened near the liquid surface and a lower end opened in the liquid, an ozone-containing gas supply means for supplying an ozone-containing gas into the draft tube from the lower end side of the draft tube, and an upper end side of the draft tube And a gas collecting means for collecting ozone exhaust gas from the aerobic biological treatment apparatus.