JP6088763B2 - Sewage treatment equipment - Google Patents

Description

The present invention relates to a sewage treatment apparatus that can efficiently treat sewage without requiring an aeration apparatus or large power to supply oxygen to microorganisms.

In a biofilm method such as an activated sludge method, a catalytic oxidation method, an aerobic filter bed method, etc., aeration is generally performed in order to supply oxygen to microorganisms and aerobically treat sewage. For example, Patent Document 1 discloses a method in which treated water is circulated and aerated from the bottom in order to increase the efficiency of an aerobic filter bed.
As an aeration method, there are a method of blowing air from a blower into a diffuser pipe and a mechanical aeration method, both of which consume a large amount of power.

On the other hand, as a method that does not perform aeration, there are a rotating disk method and a sprinkling filter bed method.
In the sewage treatment apparatus using the rotating disk method, a semi-submerged disk is rotated to take in oxygen from the air, and thus a motor and a speed reducer are required, and thus a large amount of power is required.
Moreover, in the sewage treatment apparatus using the sprinkling filter bed method disclosed in Patent Document 2, oxygen is taken in from the air, but the power of the pump for circulating and dispersing the sewage from the upper part of the filter bed is necessary. is there.
Thus, any conventional sewage treatment apparatus requires a large power for supplying oxygen.

JP 2005-13927 A JP 2003-71478 A

An object of the present invention is to provide a sewage treatment apparatus that can efficiently treat sewage without requiring an aeration apparatus or large power to supply oxygen to microorganisms.

The present invention is a sewage treatment apparatus for treating sewage and discharging the obtained treated water, a sewage treatment tank filled with a filter medium, a filter medium support frame for dividing the sewage treatment tank in multiple stages, and an air and air intake tube holes are formed intake, and an upper Symbol sewage treatment tank connected to the drainage device, space is provided between the filter medium to be filled in the lower portion of the filter medium support cradle and the filter medium support cradle The air intake hole is provided in the space, and the drainage device is a siphon-type drainage device or a load-sensing open / close drainage device, and the filter media is immersed in sewage or treated water and the filter media is exposed to air. It is a sewage treatment apparatus which repeats intermittently.
The present invention is described in detail below.

The present inventors have found that it is possible to efficiently treat sewage without requiring an aeration apparatus or large power for supplying oxygen by intermittently repeating immersion and exposure of the filter medium, The present invention has been completed.

The sewage treatment apparatus of the present invention treats sewage and discharges the obtained treated water.
The sewage treatment apparatus of the present invention has a sewage treatment tank and a drainage device.

The sewage supply method to the sewage treatment apparatus is not particularly limited as long as a general method such as pumping is used, but as a sewage supply pipe so that sewage can be supplied at low cost without using power, etc. It is preferable that sewage is supplied into the sewage treatment tank by a natural flow pipe.

The material constituting the sewage supply pipe is not particularly limited as long as it is a material that is durable against sewage. For example, resins such as polyethylene and vinyl chloride, fiber reinforced plastics, steel, ductile cast iron, etc. And reinforced concrete (fume tube).

The cross-sectional shape in the pipe radial direction of the sewage supply pipe is not particularly limited as long as it is a cross-sectional shape that can be used as a pipe through which sewage flows.For example, a rectangular, circular, oval, etc. pipe with a closed cross-section is mentioned, A circular shape is preferred.

Although the pipe diameter of the said sewage supply piping is not specifically limited, A preferable minimum is 100 mm and a preferable upper limit is 3000 mm. If the pipe diameter of the sewage supply pipe is less than 100 mm, the sewage may not be transferred due to solid matter in the sewage.
In the present specification, the “pipe diameter” means the diameter of the circumscribed circle of the inner cross section of the pipe.

The sewage supply pipe preferably has water permeability, and can be sprinkled from the sewage supply pipe onto the filter medium by being installed on the upper part of the filter medium described later.
Examples of means for imparting water permeability to the sewage supply pipe include a method of providing an opening in the sewage supply pipe.

As long as the shape of the opening of the sewage supply pipe is not clogged by solid matter in the sewage and the sewage is uniformly sprayed on the filter medium, it can be any of a circle, an ellipse, an ellipse, a corner, etc. However, a circular shape is preferable in terms of ease of processing.
The number of openings in the sewage supply pipe is preferably adjusted as appropriate so that the sewage is not clogged with solid matter in the sewage and the sewage is uniformly sprayed on the filter medium.

A preferable lower limit of the size of the opening of the sewage supply pipe is 1 mm, and a preferable upper limit is 50 mm. If the opening of the sewage supply pipe is less than 1 mm, clogging may occur due to solid matter in the sewage. If the opening of the sewage supply pipe exceeds 50 mm, the sewage may not be uniformly sprayed on the filter medium. The more preferable lower limit of the size of the opening of the sewage supply pipe is 10 mm, and the more preferable upper limit is 30 mm.

The sewage treatment tank is filled with a filter medium made of a carrier intended to attach microorganisms.
The above carrier is a granular or small piece material used for adhering aerobic microorganisms or anaerobic microorganisms and is generally used by flowing in water, and about 1 to 4 weeks have passed since the start of sewage water flow. After that, aerobic microorganisms and anaerobic microorganisms naturally adhere to the carrier and grow.
In the filter medium, the material constituting the carrier is not particularly limited, and examples thereof include resins such as polyethylene, polypropylene, and polyurethane, and ceramics. When the carrier is made of a hydrophobic material such as polyethylene or polypropylene, it is preferable that the carrier is subjected to a hydrophilization treatment because the carrier needs water permeability.

The carrier needs to contact oxygen and microorganisms efficiently, has a large specific surface area, and is not easily clogged. Therefore, a fibrous body, a foamed body, a porous body, a net-like body or the like is used. preferable. Among these, a foam is more preferable from the viewpoint of increasing water retention, and an open-cell type foam is more preferable than the closed-cell type from the viewpoint of allowing sewage to penetrate into the carrier.

When the carrier is a fibrous body or a foam, it is preferable that the porosity is high in order to increase the specific surface area. Specifically, the porosity is preferably more than 50%, more preferably more than 80%.
In the present specification, the “void ratio” means the percentage of the gap per unit volume expressed as a percentage.

The shape of the carrier is not particularly limited, and examples thereof include a spherical shape, a rectangular parallelepiped shape, a cubic shape, a sheet shape, a fiber shape, and a net shape. Further, in order to prevent the filter medium from flowing out, the carrier may be used by being enclosed in a highly water-permeable container, such as a mesh or a porous tube (carrier holding tube).

The filter medium preferably has a volume of 100 mm ³ or more and less than 100,000 mm ³ . If the volume per filter medium is less than 100 mm ³ , the filter medium may flow out along with the sewage. If the volume per filter medium is 100,000 mm ³ or more, the water permeability to the inside of the filter medium is insufficient and high purification performance may not be obtained.

In the sewage treatment apparatus of the present invention, the filter medium intermittently repeats immersion with sewage or treated water and exposure of the filter medium with air. Therefore, it is preferable that the height and filling rate of the filter medium in the sewage treatment tank are adjusted so that the filter medium can appropriately repeat the immersion with sewage or treated water and the exposure with air.

When the height of the sewage treatment tank is high, if the filter medium is filled in one stage, the filter medium is consolidated and air does not easily pass through. Therefore, it is preferable to fill the filter medium in multiple stages. Examples of the method of filling the filter medium in multiple stages include a method of providing a filter medium support frame having an opening through which sewage or treated water passes to classify the inside of the sewage treatment tank.

In the sewage treatment tank, the preferred lower limit of the height per stage filled with the filter medium is 10 mm, and the preferred upper limit is 2000 mm. When the height for filling the filter medium is less than 10 mm, the contact time between the sewage and the filter medium is shortened, so that high purification performance may not be obtained. If the height at which the filter medium is filled exceeds 2000 mm, the amount of air in the sewage treatment tank may be insufficient and high purification performance may not be obtained. The minimum with more preferable height which fills the said filter medium is 100 mm, and a more preferable upper limit is 500 mm.

The material for the filter medium support frame is appropriately selected from those having corrosion resistance to sewage and capable of withstanding the load of the filter medium containing sewage. Specifically, for example, a metal punching plate or a resin net is preferable.

The opening part of the said filter-medium support stand is provided in order to let a sewage or treated water pass. The size of the opening of the filter medium support frame is appropriately adjusted so that the filter medium does not fall and clogging is unlikely to occur.

When the filter medium is packed in multiple stages, it is preferable to provide a space between the filter medium support frame and the filter medium charged below the filter medium support frame in order to improve the air flow. The preferable lower limit of the height of the space between the filter medium support frame and the filter medium is 10 mm, and the preferable upper limit is 50 mm. If the height of the space between the filter medium support frame and the filter medium is less than 10 mm, the passage of air may deteriorate and high purification performance may not be obtained. When the height of the space between the filter medium support frame and the filter medium exceeds 50 mm, the filling rate of the filter medium decreases, and thus high processing efficiency may not be obtained. A more preferable lower limit of the height of the space between the filter medium support frame and the filter medium is 20 mm.

The sewage treatment tank is filled with an air intake port for taking in air from the outside of the sewage treatment tank, an air intake pipe serving as an air passage in the sewage treatment tank, and a filter medium in order to promote air intake. It is preferable to provide an air intake hole formed in the air intake pipe for supplying air to the portion.
The diameter of the air intake port is preferably 50 to 200 mm, the diameter of the air intake tube is preferably 50 to 200 mm, and the diameter of the air intake hole is preferably 10 to 50 mm.

The air intake hole provided in the air intake pipe is preferably provided in the position of the space between the above-described filter medium support frame and the filter medium.
The number of air intake pipes and the number of air intake holes are appropriately adjusted according to the size of the sewage treatment tank so that oxygen can be sufficiently supplied to the filter medium.

The shape of the outer tube of the sewage treatment tank is not particularly limited, and examples thereof include a columnar shape, a rectangular parallelepiped shape, a cubic shape, and an ellipsoidal shape. A known large-diameter pipe such as a GPP pipe can also be used as the outer pipe of the sewage treatment tank.

The material of the outer pipe of the sewage treatment tank is not particularly limited as long as it has a strength that can withstand the fluctuation of the water level in the sewage treatment tank and the earth pressure at the time of burying. For example, fiber reinforced plastics, glass fiber reinforced plastics Steel, steel plate, concrete and the like.

The sewage treatment apparatus of the present invention has a mechanism that intermittently repeats immersion of the filter medium with sewage or treated water and exposure of the filter medium with air. Such a mechanism is not particularly limited as long as the treatment performance or the like of the sewage treatment apparatus is obtained. For example, a mechanism that starts discharge of treated water by the drainage device when the water level in the sewage treatment tank reaches a certain height. And / or a mechanism for starting the discharge of the treated water from the drainage device when a certain time has elapsed since the previous discharge of the treated water.

Since the drainage device does not require the use of a water level sensor or a pump to start drainage, it is preferably a siphon drainage device or a load sensing open / close drainage device.
In the present specification, the “siphon drainage device” means a drainage device using a siphon that uses a siphon tube to move a liquid using a pressure difference caused by a difference in liquid level. . In addition, the above-mentioned “load sensing open / close drainage device” has a mechanism that opens a drainage port by the action of a spring or the like when a constant load is applied, and closes the drainage port when the drainage flow rate decreases. Means device.

When sewage is supplied from the upper part of the filter medium in a state where sewage or treated water is not accumulated in the sewage treatment tank, the water level in the sewage treatment tank gradually rises and the filter medium is immersed.
When the drainage device is a siphon drainage device, when the water level in the sewage treatment tank reaches the upper end of the siphon tube, the siphon works and the treated water is discharged at once.
At this time, the filter medium comes into contact with air (oxygen), and the sewage in which the filter medium is immersed is aerobically decomposed by microorganisms attached to the filter medium.
When the sewage is supplied, the water level in the treatment tank rises again, but oxygen is continuously supplied from the air to the part where the filter medium is not immersed, and aerobic decomposition by microorganisms adhering to the carrier occurs. proceed.
When the water level of the sewage again exceeds the upper end of the siphon tube, the siphon works and the treated water is discharged at once, and this cycle is repeated thereafter. The same cycle is repeated even in the case of a load sensing open / close drainage device.

In the siphon drainage device, the upper end of the siphon tube is preferably higher than the uppermost surface of the filter medium in order to sufficiently immerse the entire filter medium.
In addition, the siphon tube preferably has a large drainage capacity so that the amount of drainage is larger than the amount of sewage flowing into the sewage treatment tank in order to bring the entire filter medium into contact with air during drainage, and is supplied to the sewage treatment tank. When the amount of sewage is large, a plurality of siphon tubes may be installed.

In addition, the above drainage device is a combination of a water level sensor and a pump. When the water level in the sewage treatment tank exceeds the top surface of the filter medium, the water level sensor reacts and the pump is activated to start draining. The pump may stop when the water level reaches the bottom of the sewage treatment tank.

ADVANTAGE OF THE INVENTION According to this invention, in order to supply oxygen to microorganisms, an aeration apparatus and a big motive power are not required, but the sewage treatment apparatus which can process sewage efficiently can be provided.

FIG. 1 is a radial cross-sectional view showing an example of the sewage treatment apparatus of the present invention. FIG. 2 is a longitudinal sectional view showing an example of the sewage treatment apparatus of the present invention. FIG. 3 is a longitudinal sectional view showing a case where (a) the water level in the sewage treatment tank 1 is high and (b) a case where the water level in the sewage treatment tank 1 is low in FIG.

Hereinafter, the sewage treatment apparatus of the present invention will be described in more detail with reference to the drawings. However, the present invention is not limited only to the embodiments shown in these drawings.

FIG. 1 is a radial sectional view showing an example of the sewage treatment apparatus of the present invention, and FIG. 2 is a longitudinal sectional view showing an example of the sewage treatment apparatus of the present invention.
In the sewage treatment apparatus shown in FIGS. 1 and 2, the shape of the sewage treatment tank 1 is cylindrical. In the sewage treatment tank 1, a sewage supply pipe 2 is connected from the outside of the sewage treatment tank 1. An opening is formed in the sewage supply pipe 2, and sewage can be supplied into the sewage supply pipe 2 from the opening as shown by arrows in FIGS. In the sewage treatment tank 1, the lower part of the sewage supply pipe 2 is filled with a filter medium 3 made of a carrier for adhesion of microorganisms in multiple stages (three stages) by a filter medium support frame 4. The filter medium support frame 4 has an opening through which sewage or treated water passes. A space 5 is provided between the filter medium support frame 4 and the filter medium 3 filled in the lower part of the filter medium support frame 4. The sewage treatment tank 1 is filled with an air intake 6 for taking in air from the outside of the sewage treatment tank 1, an air intake pipe 7 serving as a passage for air in the sewage treatment tank, and a filter medium 3. An air intake hole 8 for supplying air is provided. The air intake hole 8 is formed at the position of the space 5 in the air intake pipe 7.

The sewage treatment apparatus shown in FIGS. 1 and 2 has a siphon drainage device including a siphon suction port 9 and a siphon pipe 10.
The sewage treatment tank 1 and the siphon tube 10 are connected via a siphon suction port 9. When the siphon is activated, the water surface in the sewage treatment tank 1 is lowered to the bottom, and the filter medium 3 at the bottom can also be exposed to the air, so that the treatment efficiency is increased. 1 is installed at the bottom. The upper end of the siphon tube 10 is positioned higher than the uppermost surface of the filter medium 3 in order to sufficiently immerse the entire filter medium 3.

FIG. 3 is a longitudinal sectional view showing a case where (a) the water level in the sewage treatment tank 1 is high and (b) a case where the water level in the sewage treatment tank 1 is low in FIG.
By supplying sewage into the sewage treatment tank 1 from the opening of the sewage supply pipe 2, the water level in the sewage treatment tank 1 rises and the entire filter medium 3 is sufficiently immersed and exceeds the upper end of the siphon tube 10 (see FIG. 3 (a), the water level A), and the action of the siphon works, and as shown by the arrows in FIG. 3 (a), the treated water passes through the siphon suction port 9 and the siphon tube 10 all at once. Discharged. As the treated water is discharged, the water level in the sewage treatment tank 1 is lowered (the water level B in FIG. 3B), and the air taken from the outside of the sewage treatment tank 1 through the air intake 6 is air. The air passes through the intake pipe 7 and is sent to the filter medium 3 from an air intake hole 8 provided at the position of the space 5 in the air intake pipe 7. As a result, the sewage in which the filter medium 3 is immersed is aerobically decomposed by microorganisms attached to the filter medium 3. Such a cycle of immersion and exposure of the filter medium 3 is intermittently repeated, so that wastewater is automatically treated and discharged.

ADVANTAGE OF THE INVENTION According to this invention, in order to supply oxygen to microorganisms, an aeration apparatus and a big motive power are not required, but the sewage treatment apparatus which can process sewage efficiently can be provided.

DESCRIPTION OF SYMBOLS 1 Sewage treatment tank 2 Sewage supply piping 3 Filter medium 4 Filter medium support stand 5 Space 6 Air intake port 7 Air intake tube 8 Air intake hole 9 Siphon suction port 10 Siphon tube

Claims (1)

A sewage treatment apparatus for treating sewage and discharging the obtained treated water,
A sewage treatment tank filled with a filter medium; a filter medium support frame that divides the sewage treatment tank in multiple stages ; an air intake pipe having an air intake hole; and a drainage device connected to the sewage treatment tank. And
A space is provided between the filter medium support frame and the filter medium filled in the lower part of the filter medium support frame, and the air intake hole is provided in the space,
The drainage device is a siphon drainage device or a load-sensing open / close drainage device,
A sewage treatment apparatus characterized by intermittently repeating the immersion of a filter medium with sewage or treated water and the exposure of the filter medium with air.

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