JP3061838B2 - Submersible sewage purification equipment - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an underwater-type sewage purification apparatus suitable for purification of water areas in lakes and marshes where photosynthesis is active and the concentration of dissolved oxygen in water is relatively high.

[Prior Art] Various methods have been proposed for river purification. One such method is purification of sewage by aeration. This is to send air into the sewage to be purified and force the sewage and the air into contact with each other. Conventional aeration sewage purification methods include a full aeration method,
There is a partial aeration method. In the full aeration method, oxygen is supplied to the entire filter medium by aerating the entire bottom of the filter medium. on the other hand,
In the partial aeration method, only a part of the aeration tank is aerated to generate a swirling flow, thereby supplying oxygen to the entire tank.

[Problems to be Solved by the Invention] However, for sewage existing on the surface of lakes and marshes, or large rivers with a large basin area and a relatively low flow velocity,
Purification by conventional methods, such as aeration cleaning, has been very inefficient. In other words, if it is desired to aerating lakes, marshes, rivers, etc., a very large-scale and complicated structure will be required, and the cost will be enormous. . On the other hand, in the case of partial aeration, the amount of water to be purified is very large because lakes, marshes, large rivers, and the like have a large amount of water.

However, it is known that in lakes and the like, the photosynthesis is active and the dissolved oxygen concentration in the water is relatively high.

An object of the present invention is to provide a small-scale and simple-structured underwater-type sewage purification apparatus for purifying sewage in a water area in which photosynthesis such as lakes is active and the dissolved oxygen concentration in water is relatively high.

[Means for Solving the Problems] According to the present invention, in an underwater-type pollution purifying apparatus for purifying a water area in which photosynthesis is active and the concentration of dissolved oxygen in water is relatively high, a part of one end is exposed to the water surface. Submersible pump (5) having a screen (1) with suction and the other end being a suction type
, A cylindrical body (6) having a sand settling chamber (2) downstream of the screen (1), and an upper opening downstream of the sand settling chamber (2). A rectifying chamber (3) partitioned by a partition (3a) having a portion (3b), and a rectifying front partition (8) having a hole (8a) downstream of the rectifying chamber (3). And a hole (9a) in the other end of the cylinder (6)
Is provided, and a contact oxidation chamber (4) filled with a filter medium (7) is formed between the front partition (8) and the rear partition (9). .

The filter medium may be of any type known in the art.For example, the filter medium may be formed by densely assembling a large number of cylindrical bodies from which the bottom of a container with the trade name Yakult is removed and arranged at random. Is preferred.

Further, the cross-sectional area and length of the contact oxidation chamber are preferably determined so that the dissolved oxygen concentration at the outlet is 1 mg / or more.

Further, the contact oxidation chamber may be defined by providing perforated partition plates at the front and rear edges of a tube made of vinyl chloride, or may be formed by bundling a number of large-diameter pipes. Then, instead of the perforated partition plate, the vinyl chloride cylinder may be partitioned by a wire mesh.

In practicing the present invention, it is preferable to provide a filtering device in which the suction port is filled with a filter medium. In this case, it is preferable that the filtration device is a so-called attachment type that can be separated.

In addition to this, it is preferable to provide a sludge extraction pipe in the catalytic oxidation chamber. Here, it is preferable that the sludge withdrawal pipe is configured to be slidable and connected to a vacuum car, a suction pump, or other suction means.

[Operation] In the purification device configured as described above, the contact oxidation chamber is a space, and buoyancy is generated due to the space, and the device partially exposes the screen to the water, gradually submerges in the submersible pump side, and as a whole the water bottom. Along the shape. Then, the sewage sucked from the screen by the submersible pump flows into the sand settling chamber, and the settling SS is removed. Next, the water is rectified in the rectification chamber, flows into the contact oxidation chamber, and the SS is effectively captured by the filter medium of the cylindrical body. In addition, the organic matter is oxidized and purified, and is discharged from the submersible pump.

Furthermore, if a filtration device filled with filter media is provided at the suction port,
The sedimentation effect is improved and foreign matter is prevented from entering the device. As a result, maintenance and management of the device are facilitated.

In addition, if a sludge withdrawal pipe is provided in the contact oxidation chamber, the flow resistance increases due to the excessive accumulation of sludge, that is, substances that cannot be oxidized (for example, mud and solids), the aerobic portion is reduced, and the effective volume is reduced. Reduction is effectively prevented.

Embodiment An embodiment of the present invention will be described below with reference to the drawings.

In FIGS. 1 and 2, the purification device indicated generally by the reference character A is provided between the water surface WL and the water bottom WB of a water body in which photosynthesis such as lakes and the like is active and the dissolved oxygen concentration in the water is relatively high, and is substantially on the water bottom WB. It is provided along.

This device A includes a screen 1, a sand settling room 2, a rectification room 3
A contact oxidation chamber 4 and a suction-type submersible pump 5 are arranged in series. The screen 1 is partially exposed on the water surface as described later, and is configured to remove dust and the like of sewage and suck air.

The sand settling chamber 2 is configured to settle and remove sedimentable solids (SS) in sewage flowing from the screen 1.

The rectification chamber 3 is partitioned by the sedimentation chamber 2 and the partition plate 3a to the upper opening 3b, and the sewage flowing from the opening 3b is
The flow is rectified by passing through a hole 8a of a front partition plate 8, which will be described later.

The contact oxidation chamber 4 is defined by a front partition plate 8 and a rear partition plate 9 in which a vinyl chloride cylinder 6 is filled with a filter medium 7, and front and rear portions are formed with holes 8a and 9a large enough to prevent the filter medium 7 from protruding. Have been. The filter medium 7 is an arbitrary one according to a known technique. For example, it is preferable that the filter medium 7 is formed by densely assembling a large number of cylindrical bodies from which the bottom of a container with the trade name of Yakult is removed, and disposing them at random. This effectively traps suspended solids (SS) in sewage, maintains an aerobic biofilm, and performs oxidative decomposition of organic matter.

The submersible pump 5 is connected to a land-based power supply (not shown) by an electric wire 10 to suck and discharge purified water.

 Next, the operation will be described.

Since the contact oxidation chamber 4 is filled with the cylindrical filter medium 7, buoyancy is generated and the contact oxidation chamber 4 is hardly submerged. Therefore, the device A has a part of the screen 1 exposed, is gradually immersed in the submersible pump 5 side, and is set along the water bottom WB as a whole.
Further, even if the inside of the contact oxidation chamber 4 is under a negative pressure, the shape is maintained by the filled cylindrical filter medium 7, and breakage is prevented.

The sedimentation chamber 2 has, for example, a diameter D1 of 50 cm and a length L1 of 1 m, and has an internal flow velocity of, for example, 6.7 × 10 ⁻³ m / S, and
Minutes pass through sewage to remove precipitating SS.

The rectification chamber 3 has, for example, a height C of the opening 3b of 10 cm and a length L2.
Is formed at a depth of 50 cm, and the flow of sewage to the oxidation chamber 4 is rectified by the holes 8a.

The contact oxidation chamber 4 has, for example, a sectional area D2 of 0.264 m ² and a length L3
Is formed at 10 m, and the sewage has a residence time of 33
While passing through in minutes, it captures SS and oxidizes and decomposes organic matter to purify sewage. However, the dissolved oxygen concentration of the water flowing out of the outlet part, that is, the rear partition plate 9 is 1 mg /
In the following cases, shorten the length L3 so that it becomes 1 mg / or more.

In the method of sucking purified water, the amount of SS flowing into the apparatus is reduced, and blockage due to accumulation of SS is less likely to occur in the method of sucking purified water than in the case of pumping waste water from the screen 1 side.

FIG. 3 shows a main part of a second embodiment of the present invention. In the case of this embodiment, a filtration device 20 is provided in the sand settling chamber 2. The filtering device 20 is filled with a filter material, for example, the same filter material 7 as that charged in the contact oxidation chamber 4. The filter medium 7 removes relatively coarse particles before they enter the contact oxidation chamber 4.

Here, the filtering device 20 is configured as a so-called attachment, and can be freely separated or attached to the sand setting chamber 2. In mounting the filtering device 20, the protrusion 22 formed in the sand settling chamber 2 may be fitted into the concave portion 24 of the filtering device 20. By making such attachment and detachment possible, maintenance and inspection labor is greatly reduced.

FIG. 4 shows a main part of a third embodiment of the present invention. When water is sucked into the contact oxidation chamber 4 by the submersible pump 5, microorganisms adhere to the filter medium, and purification proceeds by biological action.
However, sludge D accumulates in the contact oxidation chamber 4 as shown by the dotted line in FIG.

On the other hand, according to the third embodiment of the present invention, since the drawing pipe 30 is provided, the sludge D is discharged through the drawing pipe 30 without accumulating inside the contact oxidation chamber 4. It is. That is, a large number of openings 32 are formed in the drawing tube 30, and the end of the drawing tube 30 is connected to suction means (not shown). Therefore, the sludge D that has entered the inside of the contact oxidation chamber 4 is sucked into the drawing pipe 30 through the openings 32,.
It is sucked out and discharged. If the sludge D needs to flow backward, the suction means may be removed and a fluid (water or air) suction means may be attached.

FIG. 5 shows an example in which the filtering device 20 in the embodiment of FIG. That is, the sand settling chamber 2 and the filtration device 20 are provided with fluid ports A ₁ and A ₂ , respectively, and are interconnected by a hose H. This facilitates the attachment and detachment of both.

[Effects of the Invention] Since the present invention is configured as described above,
With a small and simple structure, photosynthesis such as lakes and marshes is active, and sewage in waters having a relatively high dissolved oxygen concentration in water can be purified.

When the dissolved oxygen concentration is low, a known air diffuser can be combined to purify sewage.

Furthermore, the suction-type submersible pump is economical because the load on the pump can be reduced, and the load on the contact oxidation chamber can be reduced to prevent breakage. Further, the apparatus can be placed along the water bottom between the water surface and the water bottom. Can be set easily.

In the present invention, if a filtering device filled with a filtering material is provided in the suction port, the sand setting effect is improved, foreign substances are prevented from entering the device, and maintenance and management of the device are facilitated.

In addition, if a sludge extraction pipe is provided in the contact oxidation chamber, the water flow resistance increases, the aerobic part decreases, the effective volume decreases, etc.
Inconvenience caused by excessive accumulation of sludge is prevented.

[Brief description of the drawings]

FIG. 1 is a vertical sectional view showing one embodiment of the present invention, FIG. 2 is a flow sheet diagram, FIG. 3 is a partially enlarged view showing a main part of a second embodiment of the present invention, and FIG. 5 is a partially enlarged view showing a main part of the third embodiment, and FIG. 5 is a partially enlarged view showing a modified example of FIG. A: Purifier, 1 ... Screen, 2 ... Sanding chamber, 3
…… Rectifying chamber, 4… Contact oxidation chamber, 7… Filter media

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int. Cl. ⁷ , DB name) C02F 3/02-3/10 C02F 3/14-3/26 C02F 7/00

Claims (1)

(57) [Claims] An underwater sewage purification apparatus for purifying a water area in which photosynthesis is active and the concentration of dissolved oxygen in water is relatively high,
It has a screen (1), one end of which is exposed on the water surface, and the other end comprising a cylinder (6) connected to a suction-type submersible pump (5). Has a sedimentation chamber (2) downstream of the screen (1), and a partition plate (3) having an opening (3b) in the upper part downstream of the sedimentation chamber (2).
a rectifying chamber (3) partitioned by a), a rectifying front partition plate (8) having a hole (8a) provided downstream of the rectifying chamber (3); ) The other end of the hole (9a)
Is provided, and a contact oxidation chamber (4) filled with a filter medium (7) is formed between the front partition (8) and the rear partition (9). An underwater type sewage purification apparatus characterized by the above-mentioned.