KR960001583Y1 - Syphon-pattern sludge collector of sediment plate - Google Patents

Abstract

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Description

Cyphonic Sludge Collector at Sedimentation Basin

1 is a schematic diagram showing the working state of the sludge collector according to the prior art

2 is a cross-sectional view taken along the line I-I of FIG.

3 is a plan view showing a transfer unit of a conventional sludge collector

4 is a front elevational view showing a conventional installation structure of a wheel for moving a transfer unit.

5 is a side view of FIG.

6 is a schematic view showing the working state of the sludge collector according to the present invention

7 is a cross-sectional view taken along line II-II of FIG.

8 is a plan view showing a transfer unit of the sludge collector according to the present invention

9 is a front elevational view showing the installation structure of the wheel for moving the transfer unit of the present invention

10 is a side view of FIG.

* Explanation of symbols for main parts of the drawings

10: transfer unit 11: saddle

11a: lower part 12: wheel

13: rotating shaft 14: bearing

16 rail 17 Siphon conduit

The present invention relates to a sludge collector for removing sludge that sits on the sediment bottom of water and sewage treatment plants using the Siphon principle. The present invention relates to a siphon type sludge remover of a sedimentation basin capable of removing sludge to a site (so-called dead zone).

In general, the sewage from the sewage treatment plant is introduced into the pumping station for the removal of suspended solids and sand through the screen and sedimentation removal facility and then sent to the next process, and the sewage of the pumping station is the primary sedimentation basin-aeration tank-secondary sedimentation basin. After the sequential purification process, the secondary sedimentation basin is precipitated and then discharged into the river by adding chemicals and chlorine. In this process, sludge is deposited in each sedimentation basin, which is removed by a sludge collector. At this time, since sludge continues to settle in the sedimentation basin, it is very important to efficiently remove the sludge so that the function of the sedimentation basin does not stop.

The sludge collector, which is widely used at home and abroad, is a cyphonic device as shown in FIGS. 1 and 2 of the accompanying drawings, which is provided along the rails 2 on both sides of the settling basin 1. The large transfer unit 3, which is reciprocated at a speed, is provided as a basic component. The plurality of cyphon conduits 4 are installed in the transfer unit 3 at substantially equal intervals in the longitudinal direction of the transfer unit 3, and the vacuum pipes are sequentially connected to each of the cyphon conduits 4. All vacuum pipes are connected to a negative pressure generating means (not shown) consisting of a vacuum pump and a vacuum tank. Once the vacuum pump is operated, negative pressure is applied to the cypress conduit (4), so that the sedimentation basin (1) sinks to the bottom. Sludge (a) that is present is sucked into the inlet of the siphon conduit (4) and then discharged to the outlet. When the discharge of the sludge (a) starts, the suction-circulation-discharge cycle of the sludge continues for a predetermined time even if the negative pressure generating means is stopped, so that the vacuum pump of the negative pressure generating means is not supplied. There is no need, and thus significant energy savings can be achieved.

However, there is a dead zone that can not completely remove the sludge (a) at the bottom of the sedimentation basin with the sludge collector as described above to reduce the sludge removal efficiency, and the sludge is not removed and continues to accumulate. The accumulated sludge is depleted of dissolved oxygen and becomes anaerobic, resulting in sludge rising (Sludge Rising).

If such a phenomenon occurs, the sedimentation effect of the sludge is lowered, the water quality of the outgoing supernatant is weakened, there is a problem that it is difficult to expect an effective sludge treatment effect.

That is, in the related art, as illustrated in FIG. 1, when the transfer unit 3 having the cyphon conduit 4 is completely transferred to the left and right along the rail 2, the cyphon conduit 4 does not reach dead. Zone S ₁ (S ₂ ) was present, which would cause the lower portion 3a of the transfer unit 3 to accommodate the cyphon conduit 4 as shown in FIGS. 1 and 2 to protrude downward. When the transfer unit 3 is completely moved to the right side (solid line state of FIG. 1), the lower portion 3a contacts the corresponding wall of the sedimentation basin 1 so that the cyphon conduit 4 is connected to the right wall of the sedimentation basin 1. Inaccessibility resulted in a dead zone (S1) between the side walls of the settling basin and the siphon conduit, making sludge removal impossible for this area.

In addition, as shown in FIGS. 3 to 5, four wheels 5, which enable the transfer unit 3 to be transported along the rail 2, are provided on the outer side of the transfer unit 3, and the transfer unit 3 When the transfer unit 3 is completely moved to the left side as shown in FIG. 1 because the saddle 6 fixed to the lower part and the saddle 6 for installing the wheel 5 protrudes outward from the transfer unit 3 ( Virtual line state) The end of the saddle (6) was in contact with the top wall of the sedimentation basin (1), thereby preventing the siphon conduit (4) from accessing the lower left corner of the sedimentation basin (1), thereby sludge Dead zone (S2) that can not be removed (a) occurred.

Therefore, in order to solve this problem, the cyphon conduit 4 installed in the transfer unit 3 may be disposed close to the left wall of the sedimentation basin to remove sludge of the dead zone S2, but the dead zone S1 of the other side of the sedimentation basin may be removed. Is relatively far away and the area of the dead zone (S ₁ ) is widened, so the problem remains that one of the sludge can not be completely removed.

There is also a method to prevent the wheel 5 from protruding from the transfer unit 3, but as shown in Figs. 4 and 5, the rotation axis 7 of the wheel 5 is Since the diameter of the wheel 5 is greater than the height of the saddle 6, the upper end of the wheel 5 is hung on the lower surface of the transfer unit 3, and thus the installation of the wheel 5 is impossible.

The present invention is to solve the conventional problems as described above, the purpose is to be able to completely remove the sludge to the dead zone that could not be removed in the prior art can increase the sludge removal efficiency and better treated water A cyphonic sludge collector of a clarified clarifier is provided.

Another object of the present invention is to provide an iPhone-type sludge collector of a sedimentation basin, which is easy to disassemble and assembly of a saddle installed on a saddle and to reduce the load on each wheel.

In the above-mentioned object, a siphon conduit for sewage sludge is installed, and a siphon collector is installed to move along rails installed at both sides of the sedimentation basin to remove the sludge settled at the bottom of the sedimentation basin. It is possible to install the wheels at the bottom of each corner of the transfer unit by fixing the birds in parallel parallel to both ends of the transfer unit, and by fixing a pair of bearings to the lower end of each of the birds to install a wheel indented on the rotating shaft, By forming the lower portion of the transfer unit at least higher than the upper end of the sedimentation basin can be achieved by the siphon type sludge collector of the sedimentation basin to remove the sludge to the dead zone of the sedimentation basin by extending the movement distance of the transfer unit to the left and right.

Hereinafter, the siphon type sludge collector of the sedimentation basin according to the present invention will be described in detail by the accompanying drawings. 6 and 7 is a state diagram of the operation of the siphon collector sludge collector of the sedimentation basin according to the present invention,

8 to 10 show the installation structure of the wheel to enable the transfer of the transfer unit, the lower end portion (11a) of the saddle (11) having a pair of beams having a substantially "c" cross-section arranged evenly to each other The wheels 12 are rotatably mounted on the wheels.

That is, the wheel 12 is pressed into the intermediate point of the rotary shaft 13, a pair of bearings 14 for smoothly rotating the wheel 12 is provided at both ends of the rotary shaft 13, the bearing 14 Silver is fixed to the lower end (11a) of each of the saddle 11 by fixing means such as bolts.

At this time, it is preferable that the bearing 14 uses a split bearing to facilitate the separation and assembly of the wheel 12 and the rotary shaft 13.

The wheel 12 is installed in this way is the upper end is located in the space between the saddle 11, there is no contact portion can be installed in any position in the longitudinal direction of the saddle (11). In addition, the saddle 11 is installed at the same height in parallel to both sides of the transfer unit 10, which is not necessary because the wheel 12 is installed on the lower end (11a) of the saddle 11, the height of the transfer unit (10). This will prevent a high rise.

Then, the saddle 11 is firmly fixed to the transfer unit 10 through the joint member 15 between the transfer unit 10 and the saddle 11 and firmly fixed them with fixing means such as bolts or welding. .

Since the upper end of the wheel 12 is positioned between the saddle 11 by the installation structure of the wheel 12 as described above, there is no fear of contact with the transfer unit 10, the wheel 12 may be transferred to the transfer unit 10. It is possible to install at the lower corners, and when such a wheel 12 is installed, the wheel when the transfer unit 10 is completely moved to the left along the rail 16 (virtual line state) as shown in FIG. Since the 12 moves further to the end point of the sedimentation basin, the movement distance of the cyphon conduit 4 may also be extended to move to the dead zone (S2) area, and at least the lower end of the transfer unit 10 When the transfer unit 10 is completely moved to the right side (solid line state), the lower end of the transfer unit 10 does not contact the upper end of the sedimentation basin when the transfer unit 10 is completely moved to the right side. Of conduit (17) The movement distance is also extended to be able to move to the dead zone (S1).

Therefore, it is possible to remove the sludge in the dead zone (S1) (S2) of the sedimentation basin which was not possible to remove conventionally.

In addition, in the assembling and disassembling work of the wheel 12, the wheel 12 is installed on the saddle 11 by the split bearing 14, so only tightening or loosening the bolt of the split bearing 14 enables easy assembly and disassembly. Is easy.

On the other hand, the four wheels 12 are installed closer to the center of gravity of the transfer unit 10 than when the transfer unit 10 is installed in the lower corner of the square, when the conventional wheels protrude from the transfer unit. Since the load applied to each wheel 12 is reduced, smooth rotation of the wheel 12 is achieved, thereby facilitating movement control of the transfer unit.

As described above, according to the siphon type sludge collector of the sedimentation basin according to the present invention, the left and right movement distances of the transfer unit are further extended, so that the sludge of the dead zone, which could not be removed in the past, can be completely removed, thereby improving sludge removal efficiency. It is easy to disassemble and assemble the wheel, and has an effect of reducing the load on the wheel.

Claims (1)

In the siphon type sludge collector of the sedimentation basin, a cyphon conduit for suctioning sludge is installed, and a wheel is installed to move along rails installed on both sides of the sedimentation basin to remove the sludge that has settled at the bottom of the sedimentation basin. The saddle 11 is fixed to both ends of the transfer unit 10 in parallel and in parallel, and a pair of bearings 14 are fixed to the lower end boom 11 A of the saddle 11 to the rotary shaft 13. By installing the press-fitted wheels 12, the wheels 12 can be installed at the lower corners of each of the transfer units 10, and the lower end of the transfer unit 10 is formed at least higher than the upper end of the sedimentation basin. Cyphonic sludge collector of the sedimentation basin, characterized in that to remove the sludge to the dead zone (S1) (S2) of the sedimentation basin by extending the moving distance of the left and right.