KR102651583B1 - The pillar rotating sludge discharge apparatus of the settling tank - Google Patents

Abstract

The present invention relates to a support rotary sludge discharge device that collects settled sludge in a settling tank into a central sludge discharge groove and discharges it to the outside. More specifically, it relates to a sludge discharge groove (5) formed centrally on the lower bottom of the settling tank (2). It is installed to cover the cone-shaped discharge hopper 11 at the top, and the discharge hopper rotates by the drive shaft 3 to inflow and discharge sludge through the sludge inlet hole 12 formed on the outside. The discharge hopper 11 ), like the conventional scraper method, prevents sludge from being discharged from the sludge discharge groove (5) or backflow, traps the sludge inside the discharge hopper (11), and ensures smooth discharge by continuous inflow of sludge, so it is efficient. There is a feature that allows this to be greatly improved.

Description

{The pillar rotating sludge discharge apparatus of the settling tank}

The present invention relates to a support rotary sludge discharge device that collects settled sludge from a sedimentation tank into a central sludge discharge groove and discharges it to the outside. More specifically, a cone-shaped discharge hopper is installed on the upper part of the sludge discharge groove in the center of the bottom of the sedimentation tank and is connected to a drive shaft. The sludge is introduced and discharged while rotating, and the discharge hopper relates to a sludge rotational sludge discharge device of a sedimentation tank that smoothly discharges the sludge without accumulation or backflow, as in the conventional scraper method.

Generally, water purification plants and sewage treatment plants are equipped with settling basins to settle and separate the sludge contained in the raw water flowing into the water purification plants and sewage treatment plants.

Such a settling basin is equipped with a sludge discharge device for discharging settled sludge, and the conventional sludge discharge device described above uses various methods such as a support rotation type.

The above-described support rotary sludge discharge device vertically installs a drive shaft driven by a drive motor in the center of the sedimentation tank, and a scraper is connected to the lower part of the drive shaft to scrape sludge from the bottom and collect it into a sludge discharge groove in the center of the bottom. As the scraper rotates by the drive shaft, it scrapes the sludge from the floor and discharges it to the outside through a discharge pipe connected to the sludge discharge groove.

However, in the conventional prop rotary sludge discharge device described above, a scraper scrapes the sludge on the floor and collects it into the sludge discharge groove. However, the sludge discharge groove does not create a pressing force to discharge the sludge to the outside through the discharge pipe, so the sludge accumulates in the sludge discharge groove. There was a problem in that the sludge was not discharged smoothly as it flowed back into the sedimentation tank.

In this way, the sludge at the bottom of the sedimentation tank is not smoothly discharged under pressure and flows back into the sedimentation tank and gradually hardens, which reduces the water quality of the sedimentation tank and requires separate cleaning work to remove sludge, resulting in economic loss and operation efficiency of the device. There was a problem with it falling off.

Registered Patent No. 10-0798080 (January 18, 2008) Registered Patent No. 10-0864960 (October 16, 2008)

The present invention was invented to solve all the problems of the prior art described above. A cone-shaped discharge hopper is installed on the upper part of the sludge discharge groove at the center of the bottom of the sedimentation tank, and the sludge is introduced and discharged while rotating by a drive shaft. The discharge hopper The purpose is to ensure that sludge is discharged smoothly without accumulation or backflow, as in the conventional scraper method.

In this invention, the sludge that settles on the bottom surface sloping downward from the outside of the lower part of the sedimentation tank to the center is collected in the central sludge discharge groove by the rotation of the sludge discharge means connected to a vertical drive shaft rotated by a drive motor and discharged into the discharge pipe. In discharging to the outside through; The sludge discharge means is composed of a discharge hopper that is vertically inserted into the drive shaft and covers the upper part of the sludge discharge groove, and a connection part that connects the discharge hopper to the drive shaft to rotate together, and the discharge hopper has at least one outside of the lower part. It is characterized by forming a sludge inlet hole and rotating it by a drive shaft to allow sludge from the floor to flow in and discharge it to the outside without accumulation or backflow.

According to the present invention, the discharge hopper is characterized by being formed as a cone-shaped body whose diameter becomes narrower from the bottom to the top.

According to the present invention, the discharge hopper is characterized by forming a guide pipe extending in the rotational direction for sludge introduction outside the sludge inlet hole.

According to the present invention, the discharge hopper further radially installs a scraper on the outside that collects sludge on the floor and guides it to the guide pipe, and the scraper is characterized in that it is configured to be inclined in the direction of rotation from the center to the outside. .

According to the present invention, the connection part is composed of a ring body that is axially inserted and coupled to the drive shaft and a connecting bar connected to the inner peripheral surface of the discharge hopper, and the fastening member is inserted and fastened through the fastening hole of the coupling protrusion formed on the radial side of the ring body and the fastening hole at the tip of the connecting bar. The characteristic is that it is structured to do so.

In this invention, a conical discharge hopper is installed to cover the upper part of the sludge discharge groove formed at the center of the lower bottom of the sedimentation tank, and the discharge hopper rotates by a drive shaft to discharge sludge by flowing it into a sludge inlet hole formed on the outside. , the discharge hopper prevents sludge from being discharged from the sludge discharge groove or backflow, like the conventional scraper method, and traps the sludge inside the discharge hopper and ensures smooth discharge by continuous inflow of sludge, greatly improving efficiency. It has the effect of being

In other words, as the sludge collected in the sludge discharge groove in the conventional sedimentation tank is not discharged smoothly, it accumulates in discharge and flows back into the sedimentation tank, gradually hardening, thereby eliminating problems such as deterioration in water quality in the sedimentation tank and the need for separate cleaning work to remove sludge. It will be solved.

1 is a front cross-sectional view showing a sedimentation tank to which the present invention is applied.
Figure 2 is an enlarged view of the main part of Figure 1.
Figure 3 is a plan view of Figure 1.
Figure 4 is a perspective view showing the discharge hopper of the present invention.
Figure 5 is a plan cross-sectional configuration diagram of Figure 4.
Figure 6 is a plan view showing an example of another embodiment of the discharge hopper of the present invention applied.

Hereinafter, preferred embodiments of the present invention described above will be examined in detail with reference to the accompanying drawings.

As shown in FIGS. 1 to 6, the support rotating sludge discharge device of the sedimentation tank of the present invention uses a drive motor (M) to remove sludge from the bottom surface (2a) sloping downward from the lower outer side toward the center of the circular sedimentation tank (2). It is configured to collect sludge in the central sludge discharge groove (5) and discharge it to the outside through the discharge pipe (8) by the rotation of the sludge discharge means (10) installed and connected to the vertical drive shaft (3) rotated by.

The sludge discharge means 10 includes a discharge hopper 11 that is vertically inserted and mounted on the drive shaft 3 and covers the upper part of the sludge discharge groove 5, and the discharge hopper is connected to the drive shaft 3 to rotate together. It consists of a connection part (16).

At this time, the discharge hopper 11 forms at least one sludge inlet hole 12 on the outer side of the lower part and rotates by a drive shaft to introduce sludge from the bottom surface so that it is smoothly discharged to the outside without discharge accumulation or backflow. .

In addition, the discharge hopper 11 is formed as a cone-shaped body whose diameter narrows from the bottom to the top, so that the sludge that continues to flow into the discharge hopper is smoothly discharged to the outside without being piled up or flowing back.

It is preferable that the lower part of the discharge hopper 11 is formed to have approximately the same diameter as the upper part of the sludge discharge groove 5, but is slightly spaced apart so as not to interfere with the bottom surface 2a when rotated by the drive shaft.

And the connecting portion 16 is composed of a ring body 17 that is axially inserted and coupled to the drive shaft 3 and a connecting bar 19 coupled to the inner peripheral surface of the discharge hopper, and the coupling protrusion 18 formed on the radial side of the ring body is fastened. The drive shaft 3 and the discharge hopper 11 are configured to rotate together by inserting and fastening the fastening member into the ball 18a and the fastening hole 19a at the tip of the connecting bar.

At this time, the ring body 17 is fastened to the drive shaft 3 as a fastening member to be fixedly coupled or fixedly coupled to the drive shaft 3 by welding or other various methods.

In addition, the discharge hopper 11 can be implemented differently as shown in FIG. 6, in which a scraper 14 is further coupled to the discharge hopper 11 to scrape the sludge on the bottom surface 2a of the sedimentation tank. The idea is to scrape it up so it can be discharged more smoothly.

That is, a scraper 14 is further installed radially on the outside of the discharge hopper 11 to collect sludge on the floor and guide it to the guide pipe 13, and the scraper 14 is inclined in the direction of rotation from the center to the outside. It is configured so that the sludge collected by the scraper 14 is naturally guided to the guide pipe 13 of the discharge hopper.

As an unexplained code, 9 represents a hand rail and 20 represents a fastening member.

Next, we will look at the operation and function of the present invention configured as above.

The sludge discharge means 10 of the present invention covers the upper part of the sludge discharge groove 5 of the sedimentation tank 3 and is mounted to rotate together with the drive shaft 3.

That is, the fastening hole 18a formed in the connection bar 19 inside the discharge hopper 11 inserted into the drive shaft 3 and the coupling protrusion 18 on the outside of the ring body 17 axially inserted and coupled to the drive shaft 3. ) The discharge hopper 11 is fixedly mounted on the drive shaft 3 by inserting and fastening the fastening member at 19a.

The discharge hopper 11 of the present invention mounted in this way rotates together with the drive shaft 3, which is rotated by the drive motor M at the top of the sedimentation tank, and discharges the sludge settled in the sedimentation tank 2 into the discharge hopper 11. It is brought in and discharged.

That is, the bottom surface 2a of the sedimentation tank 2 is inclined downward from the outside to the center, so the sludge is collected from the outside of the bottom of the sedimentation tank to the center. As the discharge hopper 11 rotates in the center of the sedimentation tank, the discharge hopper ( 11) Sludge is introduced into the sludge inlet hole 12 formed on the outer side of the lower part.

At this time, the sludge inlet hole 12 of the discharge hopper 11 is formed with an induction pipe 13 extending in the direction of rotation, so that when the discharge hopper rotates, the sludge on the bottom surface flows through the induction pipe 13 into the sludge inlet hole ( 12) will flow smoothly.

In this way, the sludge that flows into the discharge hopper 11 and is collected in the sludge discharge groove 5 has a discharge hopper 11 that covers the upper part of the sludge discharge groove 5, and has a diameter that becomes narrower from the bottom to the top. It is formed as a cone-shaped body, so that the sludge continuously collected in the sludge discharge groove (5) is smoothly discharged to the outside through the discharge pipe (8) of the sludge discharge groove (5) by applying pressure.

That is, as in the conventional scraper method, the pressure for discharging the sludge collected in the sludge discharge groove 5 is weak, so a conical discharge hopper 11 is installed to prevent the sludge from accumulating or flowing back into the sludge tank. The pressurized pressure of the sludge solves the problem of stagnation or backflow and ensures smooth discharge to the outside.

In addition, in the present invention, as shown in FIG. 6, a scraper 14 is further installed radially on the outside of the discharge hopper 11, but is installed so as to be inclined in the rotation direction from the center to the outside, so that the scraper 14 and the discharge hopper 11 are installed radially. As the scraper 14 rotates, the scraper 14 scrapes the sludge on the bottom surface 2a and collects it in the center.

At this time, the sludge scraped from the floor due to the inclination of the scraper 14 is guided to the guide pipe 13 of the discharge hopper 11 and can be discharged more smoothly through the discharge hopper.

Therefore, in the present invention, a cone-shaped discharge hopper (11) is installed to cover the upper part of the sludge discharge groove (5) in the lower center of the sedimentation tank (2) to rotate with the drive shaft (3) and discharge sludge from the bottom of the sedimentation tank to the outside of the discharge hopper. The sludge is discharged by flowing into the sludge inlet hole (12). In particular, while the discharge hopper (11) covers the sludge discharge groove (5), the sludge is discharged from the sludge discharge groove (5) or flows back like a conventional scraper method. This is prevented and the sludge is smoothly discharged to the outside due to the pressurized pressure.

2: Sedimentation tank 2a: Bottom surface
3: Drive shaft 5: Sludge discharge groove
8: Discharge pipe 10: Sludge discharge means
11: discharge hopper 12: sludge inlet hole
13: guide pipe 14: scraper
16: Connection 17: Ring body
18: coupling protrusion 18a, 19a: fastening hole
19: Connecting bar

Claims (3)

By the rotation of the sludge discharge means 10 installed and connected to the vertical drive shaft 3 rotated by the drive motor M, the bottom surface 2a sloping downward from the lower outer edge of the sedimentation tank 2 to the center is formed. Therefore, the flowing sludge is introduced into the two sludge inlet holes 12 arranged facing each other with the discharge hopper 11 in between, and the side and top are covered to prevent the sludge inlet holes 12 from being blocked, thereby reducing the pressure of the accumulated sludge. Surrounding sludge is collected through the guide pipe (13), which primarily protects from In the holding rotary sludge discharge device that discharges to the outside through the provided discharge pipe (8),
The sludge discharge means 10 is mounted to rotate by a drive shaft 3 while covering the upper part of the sludge discharge groove 5 of the sedimentation tank 2, and is located inside the discharge hopper 11 inserted into the drive shaft 3. The discharge hopper 11 is connected to the drive shaft by inserting and fastening the fastening members into the fastening holes 18a and 19a formed in the coupling protrusions 18 on the outside of the ring body 17, which are axially inserted and coupled to the connecting bar 19 and the drive shaft 3. fixedly coupled to (3);
The discharge hopper 11 rotates together with the drive shaft 3, which is rotated by the drive motor M at the top of the sedimentation tank, and flows the sludge settled in the sedimentation tank 2 into the discharge hopper 11, and flows into the sedimentation tank. The bottom surface (2a) of (2) is inclined downward from the outside to the center, so the sludge is collected from the bottom outside of the sedimentation tank to the center. As the discharge hopper 11 rotates in the center of the sedimentation tank, the discharge hopper 11 is located at the lower edge of the sedimentation tank. Sludge is introduced into the sludge inlet hole 12 formed in the sludge inlet hole 12 of the discharge hopper 11, and a guide pipe 13 is formed to extend in the direction of rotation, so that when the discharge hopper rotates, the bottom surface The sludge flows smoothly into the sludge inlet hole (12) through the guide pipe (13),
Since the pressure for discharging the sludge collected in the sludge discharge groove 5 is weak, a conical discharge hopper 11 is installed to prevent the sludge from accumulating or flowing back into the sludge tank, so that the accumulated sludge is discharged by the pressurized pressure of the continuously collected sludge. In order to solve the backflow problem and smoothly discharge to the outside, the sludge that flows into the discharge hopper (11) and is collected in the sludge discharge groove (5) is covered by the discharge hopper (11) covering the upper part of the sludge discharge groove (5), and the lower part. It is formed as a cone-shaped body whose diameter narrows from top to bottom, and is smoothly discharged to the outside through the discharge pipe (8) of the sludge discharge groove (5) by pressurizing the sludge that continues to collect in the sludge discharge groove (5). And
A scraper 14 is further installed radially on the outside of the discharge hopper 11, but is installed so as to be inclined in the direction of rotation from the center to the outside, so that the scraper 14 rotates together with the discharge hopper 11 to form a scraper 14 on the bottom surface. The scraper (14) scrapes the sludge at (2a) and collects it in the center, and the sludge scraped from the bottom by the inclination of the scraper (14) is guided to the guide pipe (13) of the discharge hopper (11) and discharged to the discharge hopper. It is discharged more smoothly through
A cone-shaped discharge hopper (11) is installed on the top of the sludge discharge groove (5) in the lower center of the sedimentation tank (2) to rotate with the drive shaft (3) to discharge sludge from the bottom of the sedimentation tank. A sludge inlet hole outside the hopper is provided. (12), but the discharge hopper (11) covers the sludge discharge groove (5), preventing the sludge from being discharged from the sludge discharge groove (5) or backflow as in the conventional scraper method, and pressurizing the sludge. A support rotary sludge discharge device for a sedimentation tank, characterized in that sludge is smoothly discharged to the outside by pressure. delete delete

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