JP2001000989A - Flow control device with sewage purification function - Google Patents

Abstract

(57) [Summary] (Modified) [Problem] To prevent the death of microorganisms attached to a contact material, thereby efficiently purifying and obtaining more advanced treated water than before, or a later-stage aeration tank. Provided is a flow control device which can be miniaturized, for example, a contact aeration tank. Kind Code: A1 A flow control tank divided by an internal partition so as to be divided into two tanks communicating with each other at an upper part, wherein each of the two tanks is provided with a stripping device, a water supply pump, and activation of the water supply pump. And a flow regulating device having a sewage purifying function, wherein at least one float switch for controlling the stop is provided. Only one of the first tanks is a contact tank provided with a contact material for adhering microorganisms, a water spray device for sprinkling water on the contact material, and a sewage measuring device. A drain pipe is connected so that the sewage supplied to the contact tank from the sewage inflow pipe is sent to the next step via the separately provided sewage measuring device after being treated in the contact tank.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flow control device for use in a sewage treatment facility using microorganisms, and more particularly, to installing a contact material for retaining microorganisms therein and appropriately operating a float switch and a water sprinkler. The present invention relates to a flow rate control device having a sewage purification function, which prevents microorganisms from being killed due to drying of the contact material.

[0002]

2. Description of the Related Art Hitherto, biological treatment methods such as an activated sludge method and a contact aeration method have been known as treatment methods for domestic wastewater and other organic wastewater (hereinafter referred to as domestic wastewater).
In these domestic wastewaters, the amount and concentration of the wastewater fluctuate with time, which makes biological treatment difficult. So, usually,
A flow control device is provided in the facility, where fluctuations in the amount of water and fluctuations in concentration of the wastewater are averaged, and a certain amount of homogenized sewage is sent to a biological treatment tank at the subsequent stage.

[0003] However, such a flow control device of a sewage treatment facility only homogenizes temporal fluctuations in the amount of water and concentration in the wastewater and lacks the ability to purify the sewage. It did little to reduce or enhance the quality of treated water. Of course,
Although it is possible to install a contact material for holding microorganisms in the flow control device, it is possible to install a contact material only in a normal flow control device because the water level in the flow control tank will fluctuate greatly, Due to the longer exposure time, the contact material dries,
There is a problem that efficient purification is difficult because the attached microorganisms are killed.

[0004]

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to prevent the microorganisms attached to the contact material from being killed by preventing the contact material from drying, thereby enabling efficient purification. Another object of the present invention is to provide a flow control device capable of achieving higher water quality or reducing the size of a biological treatment tank at a later stage such as an aeration tank or a contact aeration tank.

[0005]

SUMMARY OF THE INVENTION The above objects of the present invention are as follows.
In a flow control device disposed in a sewage treatment facility, the device is a flow control tank divided by an internal partition so as to be divided into two tanks communicating with each other at an upper part, and each of the two tanks has: At least one float switch for controlling start-up and stop of the water pump and the water supply pump is arranged, and only one of the two tanks has a contact for adhering microorganisms. Material, a contact tank provided with a water sprinkling device for sprinkling water on the contact material and a sewage measuring device, and a sewage supplied to the contact tank from a sewage inflow pipe is supplied to the contact tank, and then a water feed pump A drain pipe is arranged so as to be sent to the next step by a predetermined amount via the waste water measuring device separately provided, and when the amount of waste water flowing into the contact tank becomes sufficiently large, the waste water overflows from the contact tank and is adjacent thereto. While being stored in the two return water tanks, from the first contact tank, sewage treated by microorganisms attached to the contact material to which oxygen has been given by aeration is passed through the sewage measuring device by the water supply pump. When the water level of the contact tank falls below the upper surface of the contact material, the valve of the sprinkler is opened by a float switch arranged in the contact tank, and / or The return water pump is activated to supply sewage from the return water tank to the contact tank, and a float switch for preventing idle rotation of each pump is provided in each tank, which has a sewage purification function. Achieved by a flow regulator.

[0006]

FIG. 1 is a schematic view of a conventional general purification facility. In the figure, reference numeral 100 denotes a flow control tank, 101 denotes an aeration tank, and 102 denotes a sedimentation tank. The flow control device of the present invention is used as the flow control tank 100,
By using this, the aeration tank 101 can be significantly reduced in size when the quality of the drainage can be made comparable to the conventional one. Hereinafter, the present invention will be further described with reference to the drawings.

FIG. 2 is a conceptual diagram of a flow control device 100 according to the present invention. In the figure, reference numeral 1 is a contact tank of the first tank, 2 is a return water tank of the second tank, 3 is a contact material, 4 is an aeration device, 5 is a sewage measuring device, 6 is a water supply pump, 7 is a sewage inflow port, 8 is an overflow section, 9 is a valve of a sprinkler, 10 is a return pump, and 11 is a float switch. In the contact tank 1, a contact material 3 for holding microorganisms, an aeration device 4, and a water pump 6 for sending sewage to a sewage measuring device 5 are provided. Also,
At the upper part, a sprinkler connected to the water pump 6 is provided, and a valve 9 for controlling the operation / stop of the sprinkler is provided. As shown in the figure, when the contact material 3 is fixed,
The distance between the bottom surface of the contact material and the bottom surface of the contact material tank is preferably 50 to 60 cm so as not to hinder the circulation of the sewage. The difference in height between the contact material upper surface and the overflow portion is 30.
It is preferably about 100 cm.

The sewage flowing into the contact tank 1 from the sewage inlet 7 flows out of the overflow section 8 to the return water tank 2. In the return water tank 2, an aeration device 4 and a return water pump 10 for returning sewage to the contact tank 1 are provided. In particular, it is preferable to dispose the aeration device 4 below the contact material and to aerate from the bottom of the contact material. Each water tank is provided with at least one float switch 11 for starting and stopping the pump.

The sewage flows from the sewage inlet 7 and is stored in the contact tank 1. When the contact tank 1 is full, the sewage overflows from the overflow section 8 to the return tank 2. In the contact tank 1, oxygen required for microorganisms attached to the contact material 3 is supplied by an aeration device 4 to purify sewage by the microorganisms.

Since a constant amount of sewage in the contact tank 1 is always sent to the subsequent biological treatment tank by the water supply pump 6 and the sewage measuring device 5, contact is made when the amount of sewage is small or not at all. The water level in the tank 1 decreases. When the water level in the contact tank 1 drops to a certain level near the upper part of the contact material, the float switch 11 is operated and the return water pump 10 is activated, so that the waste water is returned from the return water tank 2 to the contact tank 1. The water supply pump 6 always supplies more water than the amount of water supplied to the subsequent stage, and watering is started immediately when the valve 9 of the watering device is opened. When the valve is closed, excess water is returned to the contact tank 1 from a drain port (not shown) in the sewage measuring device.

When the contact tank 1 is full, the float switch 1
1 causes the return pump 10 to stop. By repeating this, the wastewater comes into contact with the contact material 3 for a long time, so that the wastewater can be efficiently purified. When the amount of inflow water is small and the contact material 3 is exposed from the water surface, the valve 9 of the water sprinkling device provided at the upper part of the contact tank 1 is opened, and the exposed portion is dried because sewage is sprinkled to the contact material 3. Not only can be prevented, but it can also purify sewage. In the usual trickling filter method, significant odor is a serious problem, but in the case of the present invention, since the operation time as the trickling filter method is short, there is almost no problem caused by the odor.

[0012]

According to the present invention, the contact material can contact the sewage for a long time, and an efficient sewage purification function can be added to the flow control device. Therefore, the flow control device of the present invention is used. As a result, the quality of purified water can be improved, and the size of the biological treatment tank at the subsequent stage can be reduced.

[0013]

EXAMPLES Hereinafter, the flow rate adjusting device of the present invention will be further described with reference to examples, but the present invention is not limited thereto. FIG. 3 is a diagram for explaining the operation state of the flow control device of the present invention. Fig. a shows a state in which the sewage flowing into the first flow rate adjusting tank as the contact tank overflows from the overflow section and is stored in the second flow rate adjusting tank as the return water tank.

FIG. 2B shows that the water level in the first flow control tank has dropped to the top of the contact material, and the contact material has been exposed.
The upper float switch is turned on, the return pump of the second flow control tank is started, and the wastewater in the second flow control tank is returned to the first flow control tank.

FIG. 3C shows a state in which the water return pump is stopped by the float switch at the lower part of the second flow control tank because the water level in the second flow control tank has dropped. On the other hand, since the water level of the first flow rate control tank also decreased and the contact material was exposed, the valve of the water sprinkler in the first flow rate control tank was opened by the float switch at the lower part of the second flow control tank so that the contact material was not dried. Represents the state of watering. At the point where the water level in the first flow rate adjusting tank further decreases and the water pump may possibly run idle, the water pump is stopped by the lower float switch.

Next, 3.65 m × 1
A 5.60m × 5.0m (maximum water depth) contact tank is used, and a 3.65m × 4.70m as a second flow rate adjusting tank.
× 5.0m (maximum water depth), and inflow of sewage 400
m ³ / day, and set the transfer amount 16.67m ³ / h and, Table 1
The sewage was inflowed and discharged at the ratios as shown in (1). At this time, the accumulated flow rate and water depth of each tank are shown in Table 1 together with the results of the conventional single tank.

[0017]

[Table 1]

FIG. 4 is a graph of the results of Table 1. It is apparent from FIG. 4 that the time during which the water depth of the first flow rate tank in the present invention is maintained is longer than in the case of the conventional single tank. It is understood that it is better to arrange the first flow rate adjusting tank which is the contact material tank in the present invention.

[Brief description of the drawings]

FIG. 1 is a conceptual diagram of a conventional sewage treatment facility.

FIG. 2 is a conceptual diagram of a flow control device of the present invention.

FIG. 3 is an explanatory diagram of an operation state of the flow rate adjusting device of the present invention.

FIG. 4 is a graph demonstrating that the contact material tank of the present invention can maintain the water depth more than the case of the conventional single tank.

[Description of Signs] 1 Contact tank 2 Return water tank 3 Contact material 4 Aeration device 5 Sewage measuring device 6 Water pump 7 Sewage inlet 8 Overflow section 9 Sprinkler device valve 10 Return pump 11 Float switch 100 Flow control tank 101 Air tank 102 Sedimentation tank

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 4D003 AA02 AB02 AB04 BA01 BA02 BA08 CA04 CA10 DA03 DA08 DA14 DA19 DA29 DA30 EA10 EA14 EA17 FA05

Claims (4)

[Claims] 1. A flow control device provided in a sewage treatment facility, wherein the device is a flow control tank divided by an internal partition so as to be divided into two tanks communicating with each other at an upper part, wherein the two tanks are separated from each other. Each of the tanks is provided with a plunger, a water pump, and at least one float switch for controlling the start and stop of the water pump, and only one of the two tanks is provided with microorganisms. The contact tank is provided with a contact material for attachment, a water sprinkling device for sprinkling water on the contact material, and a sewage measuring device, and sewage supplied to the contact tank from the sewage inflow pipe is treated in the contact tank. A drain pipe is arranged so that a fixed amount is sent to the next process through the sewage measuring device separately provided by the water feed pump after being performed,
When the amount of sewage flowing into the contact tank became sufficiently large, the sewage overflowed from the contact tank and was stored in the adjacent return tank of the second tank, and oxygen was given by aeration from the first contact tank. The sewage treated by the microorganisms attached to the contact material flows out to the next step through the sewage measuring device by the water supply pump, and when the water level of the contact tank falls below the upper surface of the contact material, The float switch arranged opens the valve of the water sprinkler and / or activates the return pump of the return water tank to supply sewage from the return water tank to the contact tank and to prevent each pump from running idle. Wherein the float switch is provided in each tank. 2. The flow control device having a sewage purification function according to claim 1, wherein the contact material in the contact tank is a fixed contact material, and the aeration is performed from a lower portion of the contact material. 3. The flow control device having a sewage purification function according to claim 1, wherein the two tanks constituting the flow control tank have substantially equal capacities. 4. When the water level of the contact tank falls near the upper surface of the contact material, to supply sewage from the return water tank to the contact tank,
The float switch above the contact tank is operated so that the water pump of the return water tank is started, and when the water level of the return water tank is lowered and the water pump is likely to run idle, the return pump of the water return tank is stopped. At the same time, a float switch for opening the valve of the water sprinkler and starting water sprinkling is provided at the lower part of the return water tank, the water level of the contact tank decreases, and the water pump of the contact tank may run idle. The flow control device having a sewage purification function according to any one of claims 1 to 3, wherein a float switch that operates to stop the water pump is provided at a lower portion of the contact tank.