KR100882337B1 - Settling pond having hopper-gate - Google Patents

Abstract

The present invention relates to a sludge discharge device and system, and more particularly, to effectively distribute the sludge collected in the hopper to improve the discharge efficiency of the sludge, and discharge the sludge of the sedimentation basin formed with the hopper gate which can reduce the maintenance cost Device and system.

The present invention is a sludge discharge apparatus and system of the sedimentation basin formed hopper gate, the drive unit; A scraper connected to the driving unit and transferring the sludge deposited in the sedimentation basin to a hopper; A hopper gate installed in the hopper so as to be spaced apart from the inner wall of the hopper by a predetermined distance; A wire connected to the driving unit to open and close the hopper gate; Outlet installed in the hopper; It provides a sludge discharge apparatus and system of the clarifier formed hopper gate comprising a.

Settling basin, hopper, outlet, on / off valve, scraper, sludge, hopper gate, wire

Description

Sludge discharge device of settling basin with hopper gate {SETTLING POND HAVING HOPPER-GATE}

The present invention relates to a sludge discharge device and system, and more particularly, to effectively distribute the sludge collected in the hopper to improve the discharge efficiency of the sludge, and discharge the sludge of the sedimentation basin formed with the hopper gate which can reduce the maintenance cost Device and system.

Generally, physical treatment, chemical treatment, and biological treatment methods are used to purify waste water in water treatment plant or sewage treatment plant. Of these, sludge (sludge) contained in raw water flowing into water treatment plant or sewage treatment plant using sedimentation basin, etc. ) To precipitate and separate from water.

The sludge settled in the sedimentation basin is transported to a sludge hopper (hereinafter referred to as a hopper) by a sludge collecting device and collected, and then discharged through an outlet by driving an on / off valve.

However, conventionally, the sludge collected in the hopper is condensed on the inner wall or the bottom of the hopper to discharge only the sludge around the outlet and the sludge located far from the rear and the inlet of the outlet is not smoothly discharged and continues to accumulate.

If this phenomenon continues and the surrounding sludge hardens, sludge is discharged from the supernatant or sludge containing concentration through the channel formed in the condensed sludge, resulting in deterioration of sediment water due to waste of sediment and sludge discharge. Resulted.

In order to solve this problem, it is necessary to periodically empty the sludge in the sedimentation basin and to use the manpower to remove the condensed sludge on the inner wall of the hopper, causing a lot of economic losses.

In order to solve this problem, a technique of injecting high pressure air or high pressure water into the sludge accumulated in the hopper has been used, but this has not only a problem in that the sludge is removed from the high pressure air or high pressure water sprayed portion, but also vortices are generated during the injection. There was a risk of sludge rising and scum.

Thus, the present inventors have received a patent application (patent registration No. 362,123 "precipitated sludge hopper gate") that can remove the sludge accumulated at the side of the hopper and at the same time prevent the sludge from rising.

Such "precipitated sludge hopper gate" was effective in preventing the sludge accumulated on the side of the hopper and the injuries of the sludge, but the structure that can reduce the manufacturing and maintenance costs have been required.

In order to solve the problems of the prior art as described above, the present invention is a sludge discharge apparatus and system of the hopper is formed, the drive unit; A scraper connected to the driving unit and transferring the sludge deposited in the sedimentation basin to a hopper; A hopper gate installed in the hopper so as to be spaced apart from the inner wall of the hopper by a predetermined distance; A wire connected to the driving unit to open and close the hopper gate; Outlets installed in the hopper; It provides a sludge discharge apparatus and system of the clarifier formed hopper gate comprising a.

The scraper may be mounted on the chain having a crawler shape.

The drive unit includes a first drive unit for driving a scraper; And, the second drive unit for driving a wire; It can be configured to be divided into.

The drive unit, the drive motor; A drive shaft formed in the drive motor; A scraper driving sprocket formed on the drive shaft and transmitting a driving force to the scraper; A drive wedge formed in the drive shaft and including a plunger; And a wire drive sprocket which is formed on the drive shaft and drives the wire by receiving the power of the drive shaft when the plunger is operated and coupled according to the operation of the drive wedge; It may be configured to include.

When the wire drive sprocket rotates, the rotation speed or the rotation angle of the wire drive sprocket is detected. When the wire drive sprocket is rotated by the predetermined angle or the predetermined rotation speed, the driving motor is stopped and the sludge is discharged through the discharge port. The drive wedge may be deactivated such that the plunger is pulled away from the wire drive sprocket and the drive motor driven.

As described above, according to the sludge discharge apparatus and system of the sedimentation basin in which the hopper gate according to the present invention is formed, the sludge collected in the hopper can be effectively dispersed to improve the discharge efficiency of the sludge.

In addition, the present invention has the effect of reducing the maintenance cost.

Hereinafter, with reference to the drawings will be described in detail. However, these drawings are for illustrative purposes only and the present invention is not limited thereto.

1 is a view showing the inside of the sedimentation basin in which a hopper gate to which a sludge discharge device and a system are applied according to an embodiment of the present invention is formed, FIG. 2 is a plan view of the hopper gate shown in FIG. 1, and FIG. A plan view of the drive unit shown.

First, referring to Figure 1, the sedimentation basin (P) is provided with a hopper (H) formed with the discharge port 500, the hopper gate (Hopper-Gate, 300) is provided on the upper portion of the hopper (H). In addition, the driving unit 100 is disposed above the settling basin P, and a wire 400 is provided between the driving unit 100 and the hopper gate 300, and the sludge settled in the settling basin P in the settling basin P. A scraper 220 for collecting (S) and moving it to the hopper H is connected to the above-described driving unit 100 and disposed. In this case, the amount of sludge S in the hopper H is included or the discharge time of the sludge S discharged through the discharge port 500 is included, and a sensor (not shown) for detecting the discharged sludge is included in the detection result of the sensor. It can be configured to utilize whether or not the discharge of (S), the degree of discharge, whether the drive unit 100.

Such a sludge discharge device and system of the sedimentation basin formed hopper gate according to an embodiment of the present invention largely includes a driving unit 100, a scraper 220, a hopper gate 300, a wire 400, a discharge port 500 It is configured by.

The driver 100 is a component that is operated by receiving power to generate a driving force, and may be configured to be divided into a first driver and a second driver for driving the scraper 220 and the wire 400 described below. In the present specification, an embodiment in which the scraper 220 and the wire 400 are driven by one driving unit 100 will be described as an example.

The drive unit 100 is composed of a drive motor 110, a drive shaft 120, a scraper drive sprocket 130, a drive wedge (140) and a wire drive sprocket 150.

The driving motor 110 is driven by applying power, and operates the driving shaft 120 formed in the driving motor 110.

The scraper drive sprocket 130, the drive wedge 140, and the wire drive sprocket 150 are connected to the drive shaft 120 and rotated according to the drive of the drive shaft 120. In this case, the drive wedge 140 means a solenoid device.

Among these, the scraper driving sprocket 130 transmits a driving force to the scraper 220 via the sludge collecting device 200, that is, the chain 210 according to the driving of the drive shaft 120. Then, the drive wedge 140 including the plunger (Plunger, 142) is operated by the supply of power, the plunger 142 is operated back and forth in accordance with the supply of power to be coupled to or dropped on the wire drive sprocket 150. To drive. On the other hand, the wire drive sprocket 150 receives the drive of the drive shaft 120 in accordance with the coupling of the plunger 142 to transmit and drive the driving force to the wire 400 to open and close the hopper gate 300 described below. . The wire drive sprocket 150 has a sensor (not shown) which detects the degree of rotation, that is, the rotational speed or the rotational angle of rotation, and discharges the sludge S according to the rotational speed or the rotational angle of the wire-driven sprocket 150. You can control whether or not to release.

The scraper 220 is a component of the sludge collecting device 200 connected to the driving unit 100 to move the sludge S deposited in the sedimentation basin P to the hopper H. The sludge collection apparatus 200 is composed of a crawler-shaped chain 210 connected to the drive unit 100 and a plurality of scrapers 220 mounted on the chain 210. That is, the chain 210 is driven by receiving the driving force from the driving unit 100, and the scraper 220 moves along the bottom surface of the sedimentation basin P, while the sludge S deposited on the bottom of the sedimentation basin P is hopper ( H) will be collected.

Hopper gate 300 is installed on the hopper (H) so as to be spaced apart from the inner side of the hopper (H) by a predetermined interval, and is composed of a frame 310, opening and closing supporter 320 and opening and closing means (330).

The frame 310 forms the entire frame of the hopper gate 300, and is fixedly installed on the hopper H by the fixing member 312. The frame 310 is disposed so that the inner wall of the frame 310 and the hopper H may be spaced apart from each other by a predetermined interval, that is, a gap may be formed. In this case, the gap may be formed only between any one inner wall of the hopper H in consideration of the use environment, the use efficiency, etc. of the hopper gate 300, or the gap may be formed between all inner walls. You can also adjust the gap spacing. Meanwhile, although the shape of the frame 310 is illustrated as having a rectangular shape in the drawing, it may be changed to a circle, an elliptical shape, a polygonal shape, or the like, and may be changed according to the shape of the hopper H.

The opening and closing supporter 320 is disposed outside the frame 310 and is mounted at the end of the damper shaft 334 among the components of the opening and closing means 330 described below. The opening and closing supporter 320 is connected to the wire described below is operated in accordance with the driving of the wire.

The opening and closing means 330 is connected to the opening and closing supporter 320, which is moved to open and close the frame 310 in accordance with the operation of the opening and closing supporter 320. That is, when the wire 400 is driven and the open / close supporter 320 is rotated to one side, the wire 310 is closed, and when the wire 400 is rotated to the other side, the wire 400 is moved to open the frame 310.

The opening and closing means 330 directly opens and closes the frame 310 and is connected to the opening and closing supporter 320, and the first damper 332a and one or two or more second dampers 332b disposed away from the first damper 332a. ), A damper shaft 334 for rotatably mounting the first damper 332a and the second damper 332b to the frame 310 by using a bearing 314 or the like, and the damper shaft 334 protruded to the outside. A pair of connecting bars connected to the link members 336 mounted at one end and the other end of the first and second link members 336 to transfer the driving force of the first damper 332a to the second damper 332b ( 338). In this case, the link member 336 may be omitted and the connection bar 338 may be configured to directly connect the first damper 332a and the second damper 332b, but the first and second internal parts of the frame 310 may be formed. It is preferable that the connection bar 338 connects the first and second dampers 332a and 332b to the outside of the frame 310 through the link member 336 so that the dampers 332a and 332b can be smoothly operated. .

The damper shaft 334 is coupled to the upper side of the first and second dampers 332a and 332b to become rotation axes of the first and second dampers 332a and 332b and protrudes outward through the frame 310. The protruding damper shaft 334 is provided with a link member 336, and the opening and closing supporter 320 is mounted on any one of the damper shafts 334 on which the link member 336 is mounted. At this time, the first damper 332a is mounted on the damper shaft 334 in which the open / close supporter 320 is mounted and operated according to the operation of the open / close supporter 320, and the second damper 332b is the first damper 332a. ) Is operated to receive the driving force through a connection bar 338 connecting the link member 336 to open and close the frame 310.

On the other hand, in one embodiment of the present invention has been described that one hopper gate 300 is installed in the hopper (H), but a plurality of the hopper gate 300 in the vertical direction is used according to the installation environment or use environment, etc. It may be.

One end of the wire 400 is connected to the above-described driving unit 100, and the other side of the wire 400 is connected to the hopper gate 300, that is, the opening / closing supporter 320 to open and close the hopper gate 300 according to the driving of the driving unit 100. Let's go.

Discharge port 500 is installed in the hopper (H) to suck, discharge the sludge (S) collected in the hopper (H), is provided with an on-off valve 510 for opening and closing the discharge port (500).

Hereinafter, with reference to the accompanying drawings, the sludge discharge apparatus and system of the clarifier hopper formed hopper gate according to an embodiment of the present invention according to this configuration.

Figure 4 is a view showing that the plunger of the driving unit shown in Figure 3 is operated, Figures 5 and 6 is a sludge discharge device according to an embodiment of the present invention for discharging the sludge from the sedimentation basin formed hopper gate to which the system is applied It is a figure which shows the state.

First, referring to FIGS. 1 and 3, power is applied to the drive motor 110 to operate the drive shaft 120. The driving force is transmitted to the scraper drive sprocket 130 and the drive wedge 140. Accordingly, the scraper drive sprocket 130 is driven to rotate the caterpillar-shaped chain 210 so that the scraper 220 moves the sludge S deposited in the sedimentation basin P to the hopper H to be collected.

In this case, since the wire driving sprocket 150 is not connected to the driving shaft 120, the driving unit 120 does not drive the wire driving sprocket 150, and since both of the first and second dampers 332a and 332b of the hopper gate 300 are opened, the wire driving sprocket 150 is moved by the scraper 220. The sludge S is precipitated in the hopper H through an open hopper gate 300 and a gap between the inner wall of the hopper H and the hopper gate 300.

As such, when the sludge S collected in the hopper by the scraper 220 is stored for a predetermined amount or more, the process for discharging the sludge S is started.

That is, when power is applied to the drive wedge 140 as shown in FIGS. 4 and 5, the plunger 142 is advanced and coupled to the wire driving sprocket 150. That is, the plunger 142 is inserted into the wire driven sprocket 150 to form a hole 152 or a groove having a shape capable of receiving the rotational force of the plunger 142. Thus, the plunger 142 is a wire driven sprocket. By being coupled to 150, the driving force of the drive shaft 120 can be transmitted to the wire driving sprocket 150, so that the wire driving sprocket 150 is driven.

Accordingly, the wire 400 is driven to move the opening and closing means 330 through the opening and closing supporter 320 of the hopper gate 300 to close the frame 310, that is, to close the hopper gate 300.

At this time, in the sludge discharge apparatus and the system of the sedimentation basin formed hopper gate according to an embodiment of the present invention, the sensor for detecting the degree of rotation of the wire-driven sprocket 150, that is, the number of revolutions or rotation angle, and the sludge in the hopper (H) Sensors for detecting the amount of (S) or the discharge time of the sludge (S) discharged through the discharge port 500, the discharge amount may be utilized.

The wire driving sprocket 150 is rotated as the plunger 142 of the drive wedge 140 is coupled to drive the wire 400 to close the hopper gate 300. That is, since the hopper gate 300 is closed according to the degree of rotation of the wire driven sprocket 150, it is determined that the hopper gate 300 is closed when the wire driven sprocket 150 is rotated at a predetermined rotation speed or rotation angle. It is to be no longer rotated, the operation of the drive motor 110 is stopped so that no more of the sludge (S) through the scraper 220 or the closure of the hopper gate 300 is made.

Thereafter, as illustrated in FIG. 6, the open / close valve 510 is driven to inhale and discharge the sludge S.

As such, the sludge S precipitated in the hopper H is discharged to the discharge port 500, and the sedimented water and the sludge S on the closed hopper gate 300 are moved into the hopper H.

At this time, since the hopper gate 300 is closed, the space where the sludge S can move is only a gap between the inner wall of the hopper H and the hopper gate 300. Therefore, the sedimented water and the sludge S are introduced along the inner wall of the hopper H with a strong water pressure to sweep the sludge S adhered to the inner wall of the hopper H to smoothly discharge the sludge S. It is done. At this time, the gap between the inner wall of the hopper H and the hopper gate 300 may be adjusted to adjust the water pressure flowing into the hopper H.

When the discharge of the sludge S is completed by detecting the amount of sludge S, the discharge time of the sludge S, and the discharge amount of the sludge S in the hopper H, the power supplied to the drive wedge 140 is blocked or operated. When the plunger 142 is released from the wire driving sprocket 150, the driving motor 110 is driven again so that the scraper 220 continuously collects the sludge S into the hopper H.

Here, the closed hopper gate 300 is gradually opened by the weight of the opening and closing means 330, especially the first and second dampers (332a, 332b), and after a predetermined time, the hopper gate 300 as shown in FIG. Is fully open.

In this case, the hopper gate 300 is opened by the weight of the first and second dampers 332a and 332b, and the first and second dampers 332a and 332b are formed by using an elastic member (not shown). Can be configured to open. That is, one side of the elastic member is connected to the frame 310 and the other side is connected to the first or second dampers 332a and 332b so that the first or second dampers 332a and 332b connect the hopper gate 300. When it is operated to close, when the elastic force is accumulated and the plunger 142 falls from the wire drive sprocket 150, the first and second dampers 332a and 332b are opened by the accumulated elastic force.

As such, those skilled in the art to which the present invention pertains will appreciate that the present invention may be implemented in other specific forms without changing the technical spirit or essential features thereof.

Therefore, the exemplary embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

1 is a view showing the inside of the sedimentation basin is formed hopper gate to which the sludge discharge device and system according to an embodiment of the present invention is applied.

FIG. 2 is a plan view of the hopper gate shown in FIG. 1.

3 is a plan view of the driving unit illustrated in FIG. 1.

4 is a view illustrating that the plunger of the driving unit illustrated in FIG. 3 is operated.

5 and 6 are views showing a state in which the sludge is discharged from the sedimentation basin in which the hopper gate to which the sludge discharge device and the system are applied according to an embodiment of the present invention is formed.

*** Explanation of main parts of drawing ***

Explanation of symbols on the main parts of the drawings

100: drive unit 110: drive motor

120: drive shaft 130: scraper drive sprocket

140: drive wedge 142: plunger

150: wire driven sprocket 152: hole

200: sludge collection device 210: chain

220: scraper 300: hopper gate

310: frame 312: fixing member

314: bearing 320: opening and closing supporter

330: opening and closing means 332a: first damper

332b: second damper 334: damper shaft

336: link member 338: connecting bar

400: wire 500: outlet

510: on-off valve P: settling basin

H: Hopper S: Sludge

Claims (5)

In the sludge discharge device of the sedimentation basin formed hopper gate, A drive unit; A scraper connected to the driving unit to transfer the sludge settled in the sedimentation basin to the hopper and mounted to a chain having an orbital shape; A hopper gate installed at the hopper so as to be spaced apart from the inner wall of the hopper by a predetermined distance; A wire connected to the driving unit to open and close the hopper gate; And An outlet installed in the hopper; Including but not limited to: The driving unit, A first driver for driving the scraper; And A second driver for driving the wire; Sludge discharge device of the sedimentation basin formed hopper gate characterized in that divided into. The method of claim 1, The driving unit, A drive motor; A drive shaft formed in the drive motor; A scraper drive sprocket formed on the drive shaft and transmitting a driving force to the scraper; A drive wedge formed in the drive shaft and including a plunger; And A wire drive sprocket formed on the drive shaft and configured to drive the wire by receiving power from the drive shaft when the plunger is operated and coupled according to the operation of the drive wedge; Sludge discharge device of the sedimentation basin formed hopper gate comprising a. The method of claim 2, When the wire drive sprocket rotates, By detecting the rotational speed or the rotational angle of the wire drive sprocket, the drive motor is stopped and the sludge is discharged through the outlet when rotated by a predetermined angle or a predetermined rotational speed, When the discharge of the sludge is completed, The drive wedge is released, the plunger is separated from the wire drive sprocket, and the drive motor is driven, the sludge discharge apparatus of the sedimentation basin with the hopper gate is formed. delete delete

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