KR102004886B1 - Sludge collector - Google Patents

Abstract

The purpose of the present invention is to provide a sludge collector of which structure is formed such that plates are not rubbed against sidewalls or bottom of the sludge collector. The sludge collector includes: a settling basin in which wastewater or the like is flown and settled down; two chains which are formed to be parallel to each other and moved in a caterpillar track within the settling basin; a plurality of plates which are suspended on the two chains to move along the caterpillar track according to the movement of the chains and thus, discharge sludge settled on the bottom of the settling basin by moving the sludge in a discharge unit direction; a driving sprocket which is installed in the caterpillar track having the chains rotated therein to rotate the chains; a passive sprocket which is formed to guide the chains rotated by the driving sprocket; and lateral guide wheels which are formed on both side surfaces of the plates. The plurality of plates are moved along the caterpillar track formed by the chains, the plates move the sludge settled on the bottom of the settling basin to a discharge unit by pushing the sludge when moving on the bottom of the settling basin, and the lateral guide wheels guide the side surfaces of the plates.

Description

Sludge collector

The present invention relates to a sludge collector, which is mounted on a rectangular sludge collector installed in a sedimentation basin of sewage and wastewater treatment plants, and a rectangular sludge collector for collecting sludge with a sludge collection plate.

In general, the rectangular sludge collector installed in the sedimentation basin of sewage and wastewater treatment plants is equipped with a chain that rotates along the caterpillar, so that the sludge collection plate installed in the chain can collect sludge in the sedimentation basin while traveling uniformly from side to side.

The plate of the rectangular sludge collector is moved together as the chain moves along the caterpillar, which causes a problem that friction occurs because the plate circumferential portion contacts the side wall or the bottom.

Korean Utility Model Publication No. 20-2014-0003480

An object of the present invention is to provide a sludge collector in which the structure is formed so that the plate does not rub against the side wall or the bottom.

The present invention is a sedimentation basin in which sludge is precipitated by inflow of waste water, and two chains formed in parallel with each other, which move in an infinite orbit within the sedimentation basin, and are moved along the caterpillar as the chain is moved across the two chains. A plurality of plates formed to discharge the sludge settled in the sedimentation basin in the discharge direction, a drive sprocket which is installed in the caterpillar where the chain is rotated and rotates the chain, and the chain rotated by the drive sprocket A manual sprocket formed to guide the side and side guide wheels formed on both sides of the plate, wherein the plurality of plates are moved along the caterpillar formed by the chain, and the plate is deposited at the bottom of the settler when the plate moves under the settler. Push the sludge to move to the outlet, Side guide wheel provides a sludge collector, characterized in that for guiding the sides of the plate.

It may further include a front and rear guide wheel formed adjacent to the side guide wheel.

A lower sidewall rail is formed on the lower sidewall of the sludge collector, a bottom rail is formed on the bottom, and the side guide wheel is moved along the lower sidewall rail, and the front and rear guide wheels are moved along the bottom rail.

The side wall lower rail may have a cross-sectional structure in the form of a concave groove or a side convex protrusion, and the bottom rail may also have a cross-sectional structure in the form of a concave groove or a bottom convex protrusion.

An auxiliary tension maintaining device may be formed to push both sides of the plate into the lower sidewall of the sedimentation basin.

The auxiliary tension maintaining device is formed inside the lower side walls of the sludge collector, one side of the auxiliary tension maintaining device of the auxiliary caterpillar chain of the same structure, and the auxiliary plate connected to the auxiliary caterpillar chain at regular intervals; The auxiliary drive sprocket may be formed on one side of the auxiliary caterpillar chain to rotate the auxiliary caterpillar chain, and the auxiliary driven sprocket may be formed on the other side of the auxiliary caterpillar chain.

The sludge collector of the present invention has the effect that the plate can be stably moved at a constant height as the side guide wheel is moved along the side wall lower rail.

In addition, the sludge collector of the present invention has the effect that the problem due to the sludge filling through the front and rear guide wheels formed with the bottom convex protrusion and the concave wheel groove is solved.

The sludge collector of the present invention moves the auxiliary plate while the auxiliary caterpillar chain is rotated by the rotation of the auxiliary drive sprocket, and the auxiliary plate pushes both sides of the plate from the rear, so that the plate for moving the sludge has a uniform tension without deformation or distortion. Generates an effect to move the sludge.

1 is a schematic perspective view showing a sludge collector of the present invention.
2 is a schematic plan view of FIG. 1.
3 is a partially enlarged front view illustrating that the wheel is formed at the portion A in FIG. 1.
4 is a partial schematic illustrating the formation of the side wall bottom rail and the bottom rail of the sludge collector.
5 is a partially enlarged front cross-sectional view of FIG. 4.
6 is an enlarged front cross-sectional view illustrating a modification of FIG. 5.
FIG. 7A is a schematic plan view showing a lower modification example of the sludge collector 100, and FIG. 7B is a schematic front view illustrating a lower modification example of the sludge collector 100.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the accompanying drawings are only described in order to more easily disclose the contents of the present invention, but the scope of the present invention is not limited to the scope of the accompanying drawings that will be readily available to those of ordinary skill in the art. You will know.

In the description of the present embodiment, the same name and the same reference numerals are used for the same configuration and additional description thereof will be omitted.

Also, the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

1 is a schematic perspective view showing a sludge collector of the present invention, and FIG. 2 is a schematic plan view of FIG.

The sludge collector 100 of the present invention includes a sedimentation basin 110 in which waste water is introduced and sludge is precipitated, and two chains 120a and 120b formed in parallel with each other, which are moved in an orbit within the sedimentation basin 110, As the chains 120a and 120b are moved over the two chains 120a and 120b, the plurality of chains 120a and 120b move along the caterpillar and move to discharge the sludge settled in the sedimentation basin 110 toward the discharge unit 112. Plates 122, a drive sprocket 140 is installed in the caterpillar where the chain (120a, 120b) is rotated to rotate the chain (120a, 120b), and is rotated by the drive sprocket 140 A manual sprocket 150 formed to guide the chains 120a and 120b.

The drive sprocket 140 is located above the discharge part 112 and is connected to the motor unit 142 and the drive belt 144 for driving the drive sprocket 140.

The manual sprocket 150 may include a first manual sprocket 150a formed below the drive sprocket 140 vertically, a second manual sprocket 150b spaced apart from each other in a horizontal direction of the drive sprocket 140, and a first sprocket 150b. And a third manual sprocket 150c formed at one lower end of the sedimentation basin 110 in the horizontal direction of the manual sprocket 150a.

Referring again to the position of the sprockets, the third manual sprocket 150c is formed at one lower end of the settling basin 110, the second manual sprocket 150b is formed on the middle of the settling basin 110, The one manual sprocket 150a is formed at the other lower end of the sedimentation basin 110, and the driving sprocket 140 is formed at the upper side of the other side of the sedimentation basin 110.

Accordingly, the chains 120a and 120b are moved to the upper portion of the settling basin 110 through the drive sprocket 140 and then inclined downwardly through the second manual sprocket 150b and then through the third manual sprocket 150c. After the change of direction is moved along the lower portion of the sedimentation basin 110, it is formed so as to repeat the movement to the drive sprocket 140 to rise vertically via the first manual sprocket 150a.

The chains 120a and 120b are formed with two chains 120a and 120b side by side, and the plurality of plates 122 formed to be coupled and fixed in the transverse direction with respect to the moving direction of the chains 120a and 120b include a chain ( It is moved along the caterpillar formed by the 120a, 120b, when the plate 122 moves the lower portion of the sedimentation basin 110, the sludge 123 deposited on the lower portion of the sedimentation basin 110 is moved to the discharge part 112. Let's do it.

FIG. 3 is a partially enlarged front view illustrating that the wheel is formed at the portion A in FIG. 1.

The plate 122 includes side guide wheels 210 formed on both side surfaces, and front and rear guide wheels 230 and 250 formed adjacent to the side guide wheels 210.

The plate 122 has chain fastening portions 270 coupled to the chains 120a and 120b on both sides of the plate 122, and wheel bracket portions 192 are formed adjacent to the chain coupling portions 270.

The wheel bracket portion 192 is formed on both sides of the plate 122, the side guide wheels 210 are coupled to the top, and the front and rear guide wheels 230 and 250 are coupled to the side.

The side guide wheel 210 serves to prevent the side of the plate 122 from being worn by friction by colliding with the side wall 333 while the plate 122 is moved.

The front and rear guide wheels 230 and 250 serve to prevent the plate 122 from contacting the lower bottom surface 335 so that the lower portion of the plate 122 is worn by friction.

4 is a partial schematic view showing the lower rail 337 and the bottom rail 339 of the side wall 333 of the sludge collector 100, FIG. 5 is a partially enlarged front sectional view of FIG. 4, and FIG. 6 is FIG. 5. An enlarged front sectional view showing a modification of.

In the lower part of the sludge collector 100 according to the present invention, a lower rail 337 is formed on the side wall 333 as shown in FIG. 4, and a bottom rail 339 is formed on the bottom of the sludge collector 100. Side guide wheel 210 is moved along the, and the front and rear guide wheels (230, 250) are moved along the bottom rail (339).

FIG. 5 is a partial schematic view showing a case in which the lower side rail 337 has a cross-sectional structure in the form of a concave groove 341, and the bottom rail 339 also has a cross-sectional structure in the form of a concave groove 341. 6 is a schematic view illustrating a case in which the side rail 333 has a cross sectional structure in the form of the side wall convex protrusion 343, and the bottom rail 339 also has a cross sectional structure in the form of the bottom convex protrusion 345. to be.

The sludge collector 100 of the present invention has a cross-sectional structure in which the side rail 333 lower rail 337 has a concave groove 341, as shown in FIG. 5, and the bottom rail 339 also has a concave groove 341-1. I can do the rescue.

In this case, the side guide wheels 210 are moved along the lower sidewalls 333 and the lower rails 337, and the plate 122 is stably moved at a constant height.

And while the front and rear guide wheels (230, 250) are moved along the bottom rail (339) plate 122 is prevented from shaking left and right.

However, the cross-sectional structure in the form of concave grooves 341 and 341-1 formed in the lower rail 337 and the bottom rail 339 of the side wall 333 as shown in FIG. 5 has some sludge in the concave grooves 341 and 341-1. There may be a problem that it can be in an alluvial state to prevent the side guide wheels 210 and the front and rear guide wheels 230 and 250 from moving.

Therefore, the sludge collector 100 of the present invention has a cross-sectional structure in which the side rails 333 and the lower rail 337 have a side wall 333 convex protrusion 343 as shown in FIG. 6, and the bottom rail 339 also has a bottom convex protrusion ( 345) can have a cross-sectional structure.

In this case, the side guide wheel 210 has a concave wheel groove 212 engaging the convex protrusions 343 of the side wall 333 is formed along the circumference of the wheel.

In addition, the front and rear guide wheels 230 and 250 are formed with concave wheel grooves 232 engaged with the bottom convex protrusion 345 along the wheel circumference.

The sludge collector 100 of the present invention has an effective side rail structure in which the problems caused by the sludge filling are solved through the side guide wheels 210 in which the side walls 333, the convex protrusions 343, and the concave wheel grooves 212 of FIG. 6 are formed. Form.

And through the front and rear guide wheels 230, 250 formed with the bottom convex protrusion 345 and the concave wheel groove 232 of Figure 6 there is an effect that the problem due to the sludge filling is solved.

FIG. 7A is a schematic plan view showing a lower modification example of the sludge collector 100, and FIG. 7B is a schematic front view illustrating a lower modification example of the sludge collector 100.

In the sludge collector 100 of the present invention, auxiliary tension maintaining devices 355a and 355b are formed at both sides of the side wall 333 in the lower portion as shown in FIG. 7.

That is, in order to prevent the plate 122 moved from the lower portion of the sludge collector 100 to be unevenly bent or warped in the process of moving the sludge, auxiliary tension simultaneously pushing both sides of the plate 122 to be moved. The holding device 355 is formed.

The auxiliary tension maintaining devices 355a and 355b are formed inside the lower side walls 333 of the sludge collector 100, and one of the auxiliary tension maintaining devices 355a of the auxiliary tension maintaining devices 355a and 355b has the same structure. One side of the auxiliary caterpillar chain 357, the auxiliary plate 359 connected to the auxiliary caterpillar chain 357 at regular intervals, and the auxiliary caterpillar chain 357 to rotate the auxiliary caterpillar chain 357. Auxiliary drive sprockets 363 formed on the auxiliary auxiliary sprocket 365 are formed on the other side of the auxiliary crawler chain 357.

A drive motor is connected to the auxiliary drive sprocket 363 to operate the auxiliary drive sprocket 363, and the drive motor is omitted in a general configuration.

The other side auxiliary tension maintaining device 355b is formed at a position opposite to the one side auxiliary tension maintaining device 355a, and the structure is the same.

As the auxiliary caterpillar chain 357 is rotated by the rotation of the auxiliary drive sprocket 363, the auxiliary plate 359 is moved, and the auxiliary plate 359 pushes both sides of the plate 122 from the rear, thereby causing sludge. The moving plate 122 generates the effect of moving the sludge with a uniform tension without deformation or distortion.

As described above, the embodiments of the present invention have been described, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the present invention can be embodied by those skilled in the art. It is self-evident to. Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and thus, the present invention is not limited to the above description and may be modified within the scope of the appended claims and their equivalents.

100: sludge collector 110: sedimentation basin
112: outlet 120: chain
122: plate 140: drive sprocket
142: motor unit 144: drive chain
150: manual sprocket 150a: first manual sprocket
150b: second manual sprocket 150c: third manual sprocket
210: side guide wheels 230, 250: front and rear guide wheels
341: concave groove 345: bottom convex protrusion
355a, 355b: auxiliary tension retaining device 359: auxiliary plate
363: auxiliary drive sprocket

Claims (5)

delete delete delete delete Sedimentation basin where wastewater enters and sludge is settled,
Two chains formed in parallel to each other and moved in an orbit in the sedimentation basin,
A plurality of plates formed to move and discharge the sludge settled in the lower part of the sedimentation basin in the direction of the discharge while moving along the caterpillar as the chain is moved over the two chains;
A drive sprocket installed on the caterpillar to which the chain is rotated, and configured to rotate the chain;
A manual sprocket configured to guide the chain rotated by the drive sprocket and
It includes side guide wheels formed on both sides of the plate,
The plurality of plates are moved along the caterpillar formed by the chain, and when the plate moves to the lower part of the sedimentation basin, the sludge deposited on the lower part of the sedimentation basin is moved to the discharge part, and the side guide wheel guides the side of the plate.
It further comprises a front and rear guide wheel formed adjacent to the side guide wheel,
A lower sidewall rail is formed on the lower sidewall of the sludge collector, and a bottom rail is formed on the bottom so that side guide wheels are moved along the lower sidewall rail, and the front and rear guide wheels are moved along the bottom rail.
The side wall lower rail has a cross-sectional structure in the form of a side wall convex protrusion, and the bottom rail is a cross-sectional structure in the form of a bottom convex protrusion,
The side guide wheel has a concave wheel groove which is engaged with the side wall convex protrusion is formed along the wheel circumference,
The front and rear guide wheels are formed along the circumference of the concave wheel groove engaging the bottom convex protrusion,
An auxiliary tension maintaining device is formed to simultaneously push both sides of the plate into both side walls of the settling basin,
One side of the auxiliary tension maintaining device of the auxiliary tension maintenance device is a secondary drive sprocket is formed on one side of the auxiliary caterpillar chain, the auxiliary plate connected to the auxiliary caterpillar chain, and one side of the auxiliary caterpillar chain to rotate the auxiliary caterpillar chain. And, the auxiliary driven sprocket is formed on the other side of the auxiliary caterpillar chain is formed,
Sludge collectors, characterized in that the other auxiliary tension maintaining device is formed in a position facing the one side auxiliary tension maintaining device.

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