WO2017221346A1 - Aeration agitator - Google Patents

Abstract

[Problem] The purpose of the present invention is to provide a high-efficiency aeration agitator which is low powered and whereby oxygen dissolving efficiency is enhanced. [Solution] The present invention is characterized by comprising: a tank for storing a treatment liquid; an air diffusion means having an air diffusion part for discharging fine bubbles, the air diffusion part being provided inside the tank; an impeller rotated by a drive device, the impeller being provided above the air diffusion part; and a control means for controlling the drive device; the air diffusion part being provided so that a plane of projection of the air diffusion part with respect to a bottom surface and a plane of projection of the impeller with respect to the bottom surface are not superposed with respect to the impeller, and the control means controlling the drive device to cause the impeller to rotate when fine bubbles are discharged into the tank from the air diffusion part.

Description

Aeration stirrer

The present invention is applied to a sewage (sewage) treatment facility using activated sludge treatment (biological treatment), for example, an aerobic / anaerobic tank or an aerobic tank of a standard reaction tank having a water depth of 7 m or less. The present invention relates to an aeration stirrer.

In a sewage treatment facility for the purpose of purifying sewage, biological treatment called the activated sludge process is performed to decompose and remove organic substances in the sewage. This activated sludge method is an aerobic microorganism treatment, and when the activated sludge method is carried out, it is necessary to send air (oxygen) into the sewage in order for the activated sludge (microorganism) to absorb the pollutant (organic matter). . For this purpose, an aeration tank is used. Such a general aeration tank is usually composed of a water tank and an air diffuser disposed on the bottom thereof with an area of about 2/3 from the entire surface.

In such an activated sludge method, it is necessary to continuously supply oxygen into water in order to maintain aerobic microorganisms. When the general aeration tank is used, the power required for supplying oxygen is the activated sludge treatment. It is so large that it accounts for about 40-50% of the power of the entire water treatment facility including (biological treatment), and energy saving is required.

In recent years, various diffusers (membranes, etc.) that supply finer bubbles have been developed in order to improve oxygen dissolution efficiency. However, the basic diffuser system has not been changed, and more energy saving is required. ing.

In sewage treatment facilities, advanced treatment for the purpose of removing nitrogen, phosphorus, etc. has become widespread in order to improve the quality of treated water. Conventionally, in aerobic / anaerobic tanks and aerobic tanks with a depth of 7 m or less, aerobic biological treatment for removing BOD (hereinafter referred to as “aerobic operation”), nitrogen, An underwater agitation type aeration apparatus capable of switching to an anaerobic biological treatment (hereinafter referred to as “anaerobic operation”) for removing phosphorus is mainly applied.

Such an underwater agitating aeration apparatus is further provided with an agitating device having an agitating blade (impeller) in the above-mentioned general aeration tank, and the air discharged from the air diffuser disposed at the lower portion of the agitating blade, It is sheared mechanically by a stirring blade into small bubbles, and the small bubbles are pushed downward by a discharge flow formed by the stirring blade, and reach the water surface from the bottom in the water tank formed by the discharge flow. The oxygen is dissolved while being fed into the circulating flow of the range and stirring in the tank, and switching operation between an aerobic operation and an anaerobic operation is performed according to the required amount of oxygen with respect to the inflowing water quality.

The underwater agitating type aeration apparatus using such an agitating device disperses the bubble diameter finely and further pushes the bubbles into the water to improve the residence time and increase the oxygen dissolution rate.

However, since the power consumed by the stirrer increases, the power consumed in the entire tank increases and it is difficult to save energy. This is because power is required to push in the force of rising bubbles by the discharge action from the stirring blade, and at the same time, shearing action to make the bubbles finer is required. In addition, the rising bubbles are entangled with the stirring blades, reducing the discharge action of the stirring blades.

Also, the bubbles sheared by the stirring blades are about 3 to 7 mm in diameter and relatively large. Therefore, oxygen in the air does not dissolve efficiently in the water, and it is necessary to supply a large amount of oxygen in order to supply the necessary amount of oxygen. As in the case of using a general aeration tank, a large amount of power is required. Necessary.

In addition, since the drive unit and the stirring blade are in water, each maintenance / inspection needs to be taken out from the tank every time maintenance / inspection is required.

Here, although it is different from the aeration tank, it is an OD tank using the oxidation ditch (OD) method, and means for preventing the liquid flow and the rising bubbles from being entangled in the wing by circulating in the long pool (endless water channel) As a prior art, for example, cited reference 1 and cited reference 2 are provided.

JP 2001-79589 A JP 2006-326558 A

However, when this technique is used, there is no problem if it is a continuous pool (endless water channel) as described above, but as shown in FIG. 8, the stirring blade c of the stirring device b is placed in the tank a in a fixed finite space. When the air bubble is installed, the bubbles discharged from the air diffuser d form a flow in which bubbles are easily removed as indicated by the arrows in the figure. The oxygen dissolution efficiency cannot be improved so as to supplement the motive power.

This invention is made | formed in view of such a situation, The place made into the subject is suppressing motive energy, when supplying oxygen required for biological treatment (activated sludge process) in water. It is to provide energy saving aeration means. As a result of repeated research, development of a high-efficiency aeration stirrer that solves these problems, greatly extends the residence time of bubbles, and improves oxygen dissolution efficiency with low power without entanglement of bubbles in the stirring blades. It came to.

In order to achieve the above object, the present invention provides a tank for storing a processing solution, an air diffuser having an air diffuser for discharging fine bubbles, and a gas diffuser provided in the tank, above the air diffuser. A stirring blade that is rotated by a driving device, and a control unit that controls the driving device, and the air diffusion portion is a projection surface of the air diffusion portion with respect to the bottom surface of the air diffusion portion. The stirring blade is provided so as not to overlap a projection surface with respect to the bottom surface, and the control means controls the driving device when the fine bubbles are discharged into the tank from the air diffuser to The wing is rotated.

The agitating blade is provided at a position where the fine air bubbles discharged by the aeration unit can be taken in by the agitation blade rotating with respect to the aeration unit, and the control means includes the rotating agitation unit. The wings take in the fine bubbles discharged from the air diffuser and rotate them at a rotation speed that allows them to be discharged downward.

Further, the air diffuser of the air diffuser is formed in an annular shape, and the stirring blade is provided above the inside of the air diffuser formed in the annular shape.

The diameter of a virtual circle that is insertable into the annularly formed air diffuser and has the maximum size and coaxial with the axis of the stirring blade is 1 with respect to the diameter of the stirring blade. The air diffuser is formed so as to be not less than 0.0 and not more than 4.0 times.

Further, the stirring blade is provided at a position between 10% and 50% of the water depth from the water surface.

In the present invention, by arranging the positional relationship between the stirring blade and the air diffuser as described above, the fine bubbles discharged from the air diffuser and rising are not pushed downward, at least, Since the fine bubbles on the side and / or upper part of the stirring blade are taken in (sucked), discharged downward, and recirculated to retain the fine bubbles, like a conventional underwater aeration apparatus. Since the rising bubbles are not pushed in and the bubbles are not entangled without shearing the bubbles, the fine bubbles can be retained with low power.

Moreover, since the power unit is above the water tank or above the water surface in the water tank, it is an aeration stirrer that can be easily inspected on the tank and can be easily maintained.

It is a vertical side view of the aeration stirring apparatus of Example 1 of this invention. It is a cross-sectional top view of the aeration stirring apparatus of Example 1 of this invention. FIG. 3 is a cross-sectional view taken along line AA in FIG. 2. It is a cross-sectional top view of the other aeration stirring apparatus of Example 1 of this invention. It is a cross-sectional top view of the further another aeration stirring apparatus of Example 1 of this invention. It is a figure which shows typically the flow of the process liquid in the water tank in the aerobic operation of the aeration stirring apparatus of Example 1 of this invention, and the state of the flow of bubbles. It is a figure which shows typically the state of the flow of the process liquid in the water tank in the anaerobic operation of the aeration stirring apparatus of Example 1 of this invention. It is a vertical side view of the stirring apparatus using the conventional OD method.

Examples of modes for carrying out the present invention are shown below.

Embodiment 1 of the present invention will be described with reference to FIGS.

As shown in FIGS. 1 to 3, the aeration stirring apparatus 1 of the present invention includes a water tank 2, a stirring means 3 for stirring a treatment liquid (for example, sewage) in the water tank 2, and a bottom portion in the water tank 2. The header pipe 4 is provided, and the air diffuser 5 is fixed to and communicates with the header pipe 4.

The water tank 2 is a bottomed rectangular or circular standard tank used at a water depth of 7 m or less, for example. In addition, the upper surface of the water tank is not particularly limited, and may have an upper part opened or a ceiling part.

The stirring means 3 is connected to, for example, a driving device 6 such as a motor provided on the water tank 2 or above the water surface in the water tank 2, and the driving device 6 suspended from the center of the water tank 2. A rotating shaft (shaft) 7, an axial flow type stirring blade 8 that is fixed to the lower end of the rotating shaft 7 and discharges treated water directly below the vertical direction, and the drive device 6 to control the stirring It comprises an agitation device comprising control means 9 for rotating the blade 8 by a predetermined amount.

Then, the control means 9 controls the driving device 6 to rotate the stirring blade 8 when bubbles are discharged from the air diffusion means 5 into the tank, whereby the processing liquid (sewage water) in the water tank is rotated. ) Is discharged downward by a predetermined amount.

Further, the stirring blade 8 causes at least the fine bubbles discharged from the aeration means 5 by the stirring blade 8 rotating to the aeration means 5 described in detail later. The control means 9 is provided at a position where it can be taken in (suctioned) from the side and / or from above, and the control means 9 is provided with the rotating stirrer blades 8 to cause the fine bubbles discharged from the air diffuser means 5 to be laterally and Incorporating from the upper side and rotating at a rotation speed capable of discharging downward, a circulating flow is formed by the downward discharging flow, and the fine bubbles are recirculated by the circulating flow.

Note that the number of rotations for rotating the stirring blade 8 by the control means 9 can be controlled to the number of rotations until the discharge flow reaches an arbitrary depth of the water tank, but the number of rotations of the stirring blade 8 is The minimum number of rotations that can form the discharge flow is sufficient.

Accordingly, the power of the stirring means 3 is a circulating flow that causes the liquid in the water tank 2 to reach the bottom of the tank and circulates the entire tank when the air diffuser 5 discharges the bubbles into the water tank 2. It is sufficient that the stirring blade 8 can be rotated with a low power enough to take in the fine bubbles passing through the side of the stirring blade 8 and discharge downward, without requiring power to form .

It should be noted that the depth reaching the lower side of the discharge flow can be set to an arbitrary depth deeper than the position of the stirring blade 8 and higher than the bottom surface of the water tank 2.

The stirring means 3 is preferably an axial flow type stirring blade 8, but is not limited to this as long as it generates a downward flow.

The header pipe 4 is, for example, a circular annular (loop-shaped) hollow vent pipe, and is provided at the bottom of the water tank 2, for example, coaxially with the rotating shaft 7 of the stirring blade 8. .

Such bottom includes the bottom of the aquarium and a position away from the bottom by a predetermined distance.

The header pipe 4 has a projection surface of the stirring blade 8 at the time of rotation with respect to the bottom surface of the water tank 2 (the projection surface is a projection surface when the bottom surface is viewed from directly above; the same applies hereinafter). The header pipe 4 is provided so as not to overlap the projection surface with respect to the bottom surface, and is disposed, for example, outside the diameter of the stirring blade 8.

The header pipe 4 may have a polygonal annular shape (loop shape) as shown in FIG. 4 in addition to a circular annular shape (loop shape). Further, the annular (loop-shaped) header pipe 4 may be partially cut away (not shown).

Further, as shown in FIG. 5, the header pipe 4 may be one in which a plurality of linear header pipe elements 4 a are arranged in a ring (loop shape) apart from each other. The header tube element 4a may be a curved or bent header element in addition to a straight line shape, and a combination of different shapes of the header tube element 4a is formed into a ring shape (loop shape). Also good.

The air diffuser 5 includes, for example, a plurality of cylindrical long diffused gas 10 having the same shape, and a diffused portion having a plurality of fine holes for releasing fine bubbles on a part of the surface of the diffused gas 10. Have

Further, the plurality of diffused gases 10 have their connecting portions 10a spaced apart from each other at a predetermined interval, for example, an equal interval, on the inner peripheral surface 4b and the outer peripheral surface 4c of the hollow header tube 4, for example. Communicatingly connected, the diffused gas 10 is disposed so as to extend radially with respect to the rotating shaft 7 of the stirring blade 8, and the plurality of diffused gases 10 form one diffused gas, and the diffused gas is diffused. The air part is formed in an annular shape (loop shape).

In addition, it is preferable that the said header pipe | tube 4 and each diffused gas 10 are arrange | positioned horizontally.

The material and shape of the air diffuser 10 are not limited as long as air is discharged from the fine holes. For example, the material of the air diffuser may be ceramic or synthetic. There are a resin-made one and a fabric formed by stretching a cloth in which fine holes are formed.

Further, the shape of the diffused gas 10 is preferable as long as it has a large projected area with a small projected area with respect to the bottom surface of the water tank. It may be a shape.

Further, the diffuser part of the diffused gas 10 may be, for example, a diffused part of which the front surface and the back surface are diffused parts, or the diffused gas 10 is cylindrical, if the diffused gas 10 is plate-shaped. If there is, for example, there is one in which the entire circumferential surface becomes an air diffuser.

When the back surface is an air diffuser, the fine bubbles released from the air diffuser rise along the peripheral surface of the air diffused in the air diffuser, but the peripheral surface is also included in the air diffuser. That is, the air diffuser is a concept that includes a place where such fine bubbles are separated from the air diffuser.

The fine holes include, for example, holes having a diameter of about 50 to 500 μm when the opening area is converted to a perfect circle, and slits having a width of 50 to 500 μm and a length of about 0.5 to 2 mm.

Then, the diffused portion of the diffused gas 10 of the diffuser means 5 is discharged from the diffused gas 10, and the fine bubbles rising right above are generated by the axial flow directly below due to the rotation of the rotary blade 8. The diffused portion of the diffused gas 10 of the diffuser means 5 is projected onto the bottom surface of the water tank 2 during rotation and the bottom surface of the diffused portion so as not to be pushed downward. In other words, the air diffuser is disposed outside the diameter of the stirring blade 8 and is formed in, for example, the annular shape (loop shape). The stirring blade 8 is provided above the inside of the air diffuser.

In addition, it can be inserted into the inner side surrounded by the other ends (inner ends) 10b of a plurality of diffused gases 10 formed in an annular shape (loop shape) connected to the inner peripheral surface 4b of the header pipe 4, and The diameter of the imaginary circle 11 coaxial with the axis of the stirring blade, which is the maximum size, is 1.0 to 4.0 times (or larger than 1.0 times) the diameter of the stirring blade 8. 4.0 times or less), and particularly preferably, the diffused gas 10 is formed so as to be 3.0 times, thereby extending the residence time of fine bubbles and entanglement with the stirring blade. It becomes possible to suppress.

Further, the air from the air diffusing means 5 is agitated by disposing the agitating blade 8 from the water surface at a position of 10% to 50%, particularly preferably 25% of the tank water depth. Entanglement to the wing is suppressed.

In addition, 12 is an air supply source (blower) which sends air to the header pipe | tube 4 connected to the said air diffusion means 5 via the air supply pipe | tube 13. As shown in FIG.

Next, the operation and effect of the aeration and agitation apparatus 1 of this embodiment will be described.

In the present invention, for example, in the water tank 2 in which the processing liquid is stored, air is sent from the air supply source 12 to the air diffuser 10 of the air diffuser 5 via the air supply pipe 13 and the header pipe 4. In addition, air is discharged into the processing liquid from the fine holes formed in the diffused portion of the diffused gas 10, and the control means 9 is controlled to rotate the stirring blade 8 by the driving device 6, thereby rotating it. The fine bubbles discharged from the air diffuser 8 are taken in at least from the side and / or above by the stirring blade 8 and discharged downward.

Due to the downward discharge flow, a circulating flow is formed around the stirring blade 8, and the fine bubbles are recirculated by the circulating flow.

The rotation of the stirring blade 8 is controlled by the control means, and a downward flow is formed by the discharge of the stirring blade, and a circulating flow that circulates the captured fine bubbles around the stirring blade is generated. What is necessary is just to rotate by the rotation speed of the grade which can be formed.

Therefore, it is not necessary to rotate the stirring blade 8 in order to form a circulating flow from the water surface to the bottom surface of the processing liquid in the tank, so that the power can be reduced.

FIG. 6 shows a diagram in which the stirring blade 8 takes in the fine bubbles on the side and the upper side of the stirring blade 8 and discharges them downward, and the bubbles are recirculated in the vicinity of the stirring blade 8.

In FIG. 6, the right side of the drawing shows the state of the treatment liquid flow in the water tank 2, and the left side of the drawing schematically shows the state of the flow of fine bubbles.

The stirring blade 8 does not push the rising fine bubbles downward, does not entangle the rising bubbles to the stirring blade, does not reduce the discharge action of the stirring blade, and despite low power, It becomes possible to extend the residence time of the fine bubbles.

The aeration stirrer 1 of the present invention causes the agitating blade 8 and the air diffuser 5 to move between the natural flow formed by the air bubbles from the air diffuser (particularly the rise that occurs when the fine air bubbles are released from the air diffuser. The stirring blade can be rotated so as not to hinder the flow), and a circulating flow is formed in the vicinity of the stirring blade by the stirring blade 8 so that the fine bubbles from the aeration means 5 are allowed to rotate. The oxygen dissolution rate is increased by extending the residence time of bubbles to increase the oxygen dissolution rate, and the oxygen dissolution efficiency can be increased with extremely low stirring power.

That is, unlike the conventional underwater agitating aeration apparatus, the aeration agitating apparatus of the present invention is not used to shear and disperse the agitating blade in order to generate fine bubbles, and at the time of aeration In order to form a circulating flow in the entire water tank, the stirring blade is not rotated with high power, and the rising bubbles are not suppressed, and the rising bubbles are not entangled. It is not necessary to rotate the motor at a high speed, and therefore, less power energy is required for the motor for stirring.

And it will be possible to reduce the equipment size and installation cost.

In addition, since the bubbles are fine, the contact area with water is larger than bubbles that are not fine, so oxygen in the air is easy to dissolve in the water, and the amount of air to supply the required amount of oxygen is low. Less energy is required and the power energy required for the air supply source can be reduced.

In addition, since fine bubbles have a small buoyancy, they tend to stay in the water tank due to the water flow from the stirring blade, and stay in the entire water tank for a long time. It can be dissolved in.

Further, by forming the air diffused portion of the air diffuser 5 from, for example, a ceramic porous body, the released air can be made into fine bubbles.

From the above, the oxygen dissolution efficiency was 20% in the conventional apparatus (in-water stirring type aeration apparatus), but in the present invention, it was 25% to 33%, and oxygen could be supplied efficiently.

Further, the stirring power can be set to 4 W / m ³ or less in the present invention compared with 5 to 6 W / m ³ in the conventional apparatus, and a high energy saving effect is obtained.

Moreover, as a result of various experimental studies, the virtual circle 11 inserted into the inner side surrounded by the inner end of the cylindrical diffused gas (or diffused part) connected to the inner peripheral surface 4b of each header pipe 4 The diameter is particularly preferably 3.0 times so that the diameter is 1.0 to 4.0 times (or greater than 1.0 and 4.0 times or less) with respect to the diameter of the stirring blade. Thus, by forming the diffused gas 10, the residence time of the fine bubbles can be extended and the entanglement of the stirring blade can be suppressed.

Further, the air from the air diffuser 5 is agitated by disposing the stirring blade from the water surface at a position between 10% and 50% of the tank water depth, particularly preferably at a position of 25%. Entanglement to the wing is suppressed.

In addition, when applied to both aerobic and anaerobic tanks and aerobic tanks of standard reaction tanks with a water depth of 7 m or less, the air supply means (blower) can be used to disperse the aeration means at a water depth. It is not necessary to update the air source, and the cost can be reduced.

Further, by stopping the air supplied from the air diffuser 5, it is possible to facilitate switching from an aerobic operation to an anaerobic operation as shown in FIG. In addition, when there is no aeration, the stirring power is only 1 W / m ³ or less, a circulation flow that circulates in the water tank can be formed, and anaerobic operation can be performed with low power.

FIG. 7 is a diagram schematically showing the state of the treatment liquid flow in the water tank 2.

Moreover, since the drive device 6 of the stirring means 3 is provided above the water tank or above the water surface in the water tank, the daily inspection can be easily performed on the water tank, compared with the conventional underwater stirring aeration apparatus, There are few maintenance and inspection work items, and maintenance is easy.

Moreover, since the inside of the air diffuser 5 is larger than the stirring blade 8, there are few maintenance / inspection work items that can be lifted to the water without draining the water tank for maintenance, and maintenance is easy. Become.

The stirring device of the present invention is used in sewage treatment facilities, sewage treatment facilities, and the like.

DESCRIPTION OF SYMBOLS 1 Aeration stirrer 2 Water tank 3 Stirring means 4 Header pipe 4a Header pipe element 4b Inner peripheral surface 4c Outer peripheral surface 5 Aeration means 6 Drive apparatus 7 Rotating shaft 8 Stirring blade 9 Control means 10 Air diffuser 10a Connection part 10b Inner end 11 Virtual Yen 12 Air supply source 13 Air supply tube

Claims (5)

1. A tank for storing the processing liquid;
   Aeration means provided in the tank and having a diffusion part for discharging fine bubbles;
   A stirring blade provided above the air diffuser and rotated by a driving device;
   Comprising control means for controlling the drive device,
   The aeration part is provided so that the projection surface of the aeration part with respect to the bottom surface and the projection surface of the agitation blade with respect to the bottom surface do not overlap with the stirring blade,
   The aeration and stirring device is characterized in that the control means controls the driving device to rotate the stirring blade when fine bubbles are discharged from the diffuser into the tank.
2. The stirring blade is provided at a position where the fine air bubbles discharged by the air diffuser can be taken in by the stirring blade rotating relative to the air diffuser,
   The aeration and agitation apparatus according to claim 1, wherein the control means takes in the fine bubbles discharged from the air diffuser by the rotating stirring blade and rotates the bubbles at a rotation speed capable of being discharged downward.
3. The air diffuser of the air diffuser is formed in an annular shape, and the stirring blade is provided above the inside of the air diffuser formed in an annular shape. Aeration stirrer.
4. The diameter of an imaginary circle coaxial with the axis of the stirring blade that can be inserted into the annularly formed diffuser and has the maximum size is 1.0 with respect to the diameter of the stirring blade. The aeration stirrer according to claim 3, wherein the air diffuser is formed so as to be 4.0 times or less.
5. The aeration stirrer according to any one of claims 1 to 4, wherein the stirring blade is provided at a position between 10% and 50% of the water depth from the water surface.

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