KR100981640B1 - Electro-penetrative type sludge decrement apparatus - Google Patents

Abstract

PURPOSE: An electroosmotic sludge reduction apparatus is provided to efficiently dehydrate sludge by gradually pressurizing the front side of the sludge and sanctioning voltage to the front side of the sludge and to remarkably shorten dehydration processing time. CONSTITUTION: An electroosmotic sludge reduction apparatus comprises: a frame; a filter cloth transport unit which rotates filter cloth infinitely; a sludge supply unit; a dehydration unit which includes a first electrode(241) which is formed on the upper side of the filter cloth and a second electrode and dehydrates a sludge by forming an electric filed; a driving unit(250) elevating the dehydration unit; and a controlling unit.

Description

Electro-Penetrative type Sludge Decrement Apparatus}

The present invention relates to an electro-permeable sludge reduction device capable of improving the dewatering efficiency for sludge, and more particularly, by depressing the same pressure stepwise and applying the same voltage to the front of the sludge, sludge can be efficiently dewatered. The present invention relates to an electrically penetrating sludge reduction device.

As is well known, a polymer flocculant is introduced into the sludge treated in the wastewater and sewage treatment plant in order to purify water, but sludge agglomerated by the polymer flocculant is very difficult to dehydrate. On the other hand, since the sludge disposal cost varies considerably according to the sludge dewatering rate, it is necessary to significantly reduce the water content of the sludge in order to reduce costs or to obtain solid components of sludge that can be recycled as fuel.

As described above, the electric permeation type sludge reduction apparatus according to the prior art for reducing the water content of the sludge is as follows.

The electro-penetrating dehydrator of Korean Patent Application No. 199-0010856 has a rotating drum having an anode electrode for removing water combined with sludge by an electric field, and a water-permeable compression belt formed to surround the outer circumferential surface of the rotating drum. And a filter belt formed to overlap the surface of the dewatering region of the rotary drum and the compression belt. That is, the electropenetrating dehydrator dehydrates the sludge by applying a constant voltage between the drum and the compression belt to form an electric field in the sludge to separate moisture from the sludge. However, the method of applying a voltage to the rotating drum is complicated in structure, the manufacturing process is complicated, and the production cost increases accordingly, maintenance is difficult because the rotating drum must be large in order to process the sludge of high capacity, and for dehydration Precise stepwise control of the electrochemical reaction is difficult.

Accordingly, in order to improve the above-mentioned problems of the electropenetrating dehydrator, the electroosmotic sludge reduction apparatus of Korean Patent No. 10-0894266 has been proposed. The main structure of the proposed electro-osmotic sludge reduction device is a sludge elevating means for dewatering the sludge supplied to the filter cloth 1600 by installing a plurality of filter cloths 1600 for transporting sludge and horizontally installed in the frame 1100. (1700).

On the other hand, the sludge elevating means 1700 is arranged in a plurality of rows in the horizontal direction in the longitudinal direction on the upper portion of the frame 1100, the sludge for pressing the sludge by controlling the pressing force for the sludge differently according to the characteristics of the waste water or sewage treatment plant sludge The number of lifting means 1700 and the crimp height of each sludge lifting means 1700 are driven differently. However, the characteristics of the sludge vary depending on the season or environment, and the thickness of the supplied sludge. Therefore, the pressing force and voltage applied to the sludge should be corrected. In the case of hardly degradable sludge, dehydration is difficult and the pressing force must be changed finely. However, the sludge lifting means 1700 arranged in a plurality of rows is not capable of fine and precise control, and has a problem in that it takes up a lot of space in the longitudinal direction.

In addition, the sludge elevating means 1700 is arranged in a plurality of rows to increase the number of lifts for dewatering the sludge increases the dehydration treatment time, thereby significantly reducing the dewatering treatment amount, the production cost and installation cost of the sludge elevating means (1700) Rapidly increasing, there was a problem that is difficult to drive.

Furthermore, the sludge elevating means 1700 arranged in multiple rows was unable to apply a constant and uniform pressure to the sludge full width. That is, when the sludge is pressurized, the dewatering rate of the sludge is changed to a high width even by the difference in the pressing height of several mm units, and therefore, the development of a technology capable of applying the same pressure to the entire sludge is required.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, an electro-permeable sludge reduction device capable of efficiently dewatering sludge by applying the same voltage to the sludge in stages and applying the same voltage to the sludge step by step. It is intended to provide.

In order to achieve the above object, according to a preferred embodiment of the present invention, a predetermined shape of the frame, formed in the longitudinal direction of the frame, the filter cloth conveying portion for rotating the filter cloth infinitely, and formed on one side of the filter cloth conveying portion, A sludge supply part for supplying sludge to the upper part of the filter cloth, a first electrode part formed on an upper side of the filter cloth conveyed to the filter cloth conveying part, and a second electrode part formed below the filter cloth to face the first electrode part. And a dewatering part for dewatering the sludge by compressing the sludge supplied to the upper part of the filter cloth conveying part by the first and second electrode parts and applying a voltage to form an electric field, and fixed to the frame above the dewatering part. And a driving unit for elevating the dewatering unit, and controlling the driving unit to control the driving unit. And a control unit for adjusting the height of attachment and controlling voltage application to the first and second electrode units, wherein the dehydration unit dehydrates the sludge supplied to the upper portion of the filter cloth conveying unit by substantially the same pressure and voltage. Provides a sludge reduction device.

In the electric permeation type sludge reduction apparatus according to the present invention, the control unit controls the first electrode portion of the dewatering portion to step down the first electrode portion in the sludge direction corresponding to the dewatering amount of the sludge in the same pressure and Voltage can be applied.

In the electro-permeable sludge reduction apparatus according to the present invention, the first electrode portion is arranged to be uniformly spaced apart from the first electrode plate that applies substantially the same pressure and voltage to the sludge, and the upper side of the first electrode plate. And a voltage terminal for applying a voltage to the first electrode plate, and a conductive member for conducting voltage to the voltage terminal.

In the electroosmotic sludge reduction apparatus according to the present invention, the first electrode portion may further include a reinforcing member for reinforcing and supporting the first electrode plate.

In the electric permeation type sludge reduction apparatus according to the present invention, the rotational speed of the interlocking shaft or the drive motor is sensed to sense the crimp height of the first electrode part, and the sludge reduction device is formed on the sludge of the first electrode part of the dewatering part by the driving part. It may further include a height detecting unit for detecting the compression height for the.

In the permeation type sludge reduction apparatus according to the present invention, the guide plate is formed by penetrating the fixing plate and fixed to the first electrode portion, and the lifting limit of the guide according to the elevation of the first electrode portion of the dehydrating portion by the driving portion is determined. It may further include a lift limit detection unit for sensing.

In the apparatus for penetrating the sludge according to the present invention, the apparatus may further include an exhaust pipe fixedly formed at the first electrode part of the dewatering part and configured to exhaust wet steam generated from the sludge which is gradually dewatered by the dewatering part.

In the apparatus for penetrating the sludge according to the present invention, the filter cloth conveying unit may further include a ventilation unit which is fixed to the frame and supplies the wet steam generated from the sludge dewatered by the dewatering unit.

According to the present invention, the first electrode portion for pressurizing the sludge is integrally formed so as to correspond to the front face of the sludge, and the sludge front face is pressed stepwise at the same pressure and the same voltage is applied, whereby the sludge can be efficiently dehydrated. have.

In addition, since the same pressure is applied to the entire surface of the sludge by the first electrode part at the same time, the dehydration treatment time is significantly shortened, the apparatus can be miniaturized compared to the dewatering throughput, and the maintenance cost is low.

1 is a schematic configuration diagram of an electropenetrating sludge reduction apparatus according to the prior art.
Figure 2a is a side view of the electroosmotic sludge reduction apparatus according to the present invention.
FIG. 2B is a plan view of the electropenetrating sludge reduction apparatus of FIG. 2A.
3A is a perspective view of a dewatering part and a driving part of the electroosmotic sludge reduction device of FIG. 2A.
3B is an enlarged perspective view of the dewatering part of FIG. 3A.
FIG. 3C is a side view of the dewatering part and the driving part of the electroosmotic sludge reduction device of FIG. 3A.

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

Figure 2a is a side view of the electro-permeable sludge reduction device according to the present invention, Figure 2b is a plan view of the electro-osmotic sludge reduction device of Figure 2a, Figure 3a is a dewatering and driving part of the electro-osmotic sludge reduction device of Figure 2a 3B is an enlarged perspective view of the dewatering part of FIG. 3A, and FIG. 3C is a side view of the dewatering part and the driving part of the electroosmotic sludge reduction device of FIG. 3A.

2A to 3C, an electro-permeable sludge reduction apparatus 200 according to the present invention includes a frame 210, a filter cloth conveying unit 220, a sludge supply unit 230, a dehydration unit 240, , The driving unit 250 and the control unit.

The frame 210 is formed of a metal material having a predetermined strength or more, and is formed in a hexahedral-shaped frame shape. The frame 210 supports a component described below and stably fixes to the ground.

The filter cloth conveying part 220 is formed in the longitudinal direction of the frame 210 and rotates the filter cloth 221 indefinitely. Here, the filter cloth conveying part 220 is a drive roller 222 formed at the end of the frame 210, a termination roller 223 formed at the front end of the frame 210, and a drive roller 222 and the end. The filter cloth 221 which rotates infinitely by the roller 223 and conveys sludge is rotated by the guide roller 224 which guides the transfer from the end roller 223 to the drive roller 222 direction, and the drive roller 222. A driving motor 225 which provides a driving force to rotate the filter cloth 221 indefinitely, and a strain cloth in the longitudinal direction of the filter cloth 221, for example, a season, weather, installation environment, sludge dewatering throughput, or a filter cloth according to the type of filter cloth. It may be made of a tension roller (tension roller) 226 that adjusts the endless rotation length of the filter cloth 221 in response to the strain in the longitudinal direction of the (221). For example, in the tension roller 226, when the filter cloth 221 increases due to the above-described filter cloth deformation factor, since the infinite rotation of the filter cloth 221 is not smooth, the position of the tension roller 226 is changed, that is, the tension roller. The 226 is retracted in the direction opposite the end roller 223 so that the filter cloth 221 is not sag by sludge.

The sludge supply unit 230 is fixedly formed on the frame 210 of the upper portion of the filter cloth 221 on which the driving roller 222 and the driving motor 225 are formed to supply sludge to a predetermined thickness on the filter cloth 221. Here, the sludge supply unit 230 is a hopper (231) for supplying the sludge supplied from the outside by the sludge inlet 231-1 to the upper portion of the filter cloth 221 by the sludge outlet 231-2, and the hopper A sludge supply amount sensor 232 for detecting a supply amount of sludge supplied to the 231, a sludge supply roller 233 for adjusting the sludge to be constantly supplied to the filter cloth 221, and a sludge supply roller 233. It may be made of a sludge feed roller driving motor (not shown) to rotate. For example, the hopper 231 serves as a storage and movement passage of the sludge, the sludge supply amount sensor 232 detects the supply amount of the sludge stored or moved in the hopper 231, the sludge supply roller 233 ) Adjusts the amount of sludge supplied to the upper part of the filter cloth 221 according to the amount of sludge detected by the sludge supply amount sensor 232 to maintain a constant thickness of the sludge transferred to the upper part of the filter cloth 221. Do it. That is, the sludge supply unit 230 may determine the thickness of the sludge supplied to the upper part of the filter cloth 221 regardless of season, weather, installation environment, dewatering amount of sludge, or water content of the sludge which may vary depending on the type of filter cloth. By keeping constant and uniform at all times, the dewatering efficiency of the sludge by the dewatering part 240 which will be described later can be predicted and the dewatering efficiency can be further improved.

The dewatering part 240 is disposed at the lower portion of the filter cloth 221 opposite to the first electrode part 241 and the first electrode part 241 formed above the filter cloth 221 conveyed by the filter cloth conveying part 220. Composed of the second electrode portion 242 is formed, the sludge supplied to the upper portion of the filter cloth transfer portion 220 by the first and second electrode portion (241, 242) is pressed and a voltage is applied to form an electric field to dewater the sludge . That is, the dewatering unit 240 dewaters the sludge by applying substantially the same pressure and voltage within a crimp height error range of several mm to the sludge full width supplied to the filter cloth conveying unit 220.

Therefore, the pressure and voltage applied to the sludge can be easily modified according to the characteristics of the sludge and the thickness of the sludge supplied from the sludge supply unit 220 according to the season or the environment. It can control, significantly reduce the installation space, reduce the number of lifting times for dewatering sludge, reduce the dewatering treatment time, thereby significantly increase the dewatering throughput, reduce manufacturing and installation costs, sludge dewatering The driving method for the control may also be easier.

Referring to FIGS. 3A to 3C, the first electrode part 241 is, for example, a first electrode plate 241-1 that applies substantially the same pressure and voltage to the sludge, and an upper side of the first electrode plate 241-1. A voltage terminal 241-3 that is uniformly spaced apart in the shape of a matrix and applies a voltage to the first electrode plate 241-1, and a conductive member that conducts the voltage to the voltage terminal 241-3. 241-4.

On the other hand, the first electrode portion 241 may further include a reinforcing member 241-5 for reinforcing and supporting the first electrode plate 241-1. That is, the reinforcing member 241-5 includes a horizontal reinforcing piece 241-5a, a horizontal reinforcing piece 241-5a, and formed in a predetermined shape substantially in parallel with the front surface of the first electrode plate 241-1. It consists of at least two or more vertical reinforcing pieces 241-5b formed in a predetermined shape in a substantially vertical direction, and the horizontal reinforcing pieces 241-5a and the vertical reinforcing pieces 241-5b are firmly fixed to each other. . Therefore, the reinforcing member 241-5 including the horizontal reinforcing piece 241-5a and the vertical reinforcing piece 241-5b effectively prevents deformation of the first electrode plate 241-1, for example, warping or sagging of the front, rear, left, and right sides. By preventing, it is possible to apply substantially the same and uniform pressure and voltage to the front surface of the sludge conveyed on the filter cloth 221.

The driving unit 250 is fixed to the frame 210 on the upper side of the dewatering unit 240, and lifts the dewatering unit 240 in a direction substantially perpendicular to the filter cloth conveyed by the filter cloth conveying unit 220.

3A to 3C, the driving unit 250 is fixedly formed on the upper side of the frame 210, and is formed on the front surface, that is, the width and width of the first electrode plate 241-1 of the first electrode unit 241. The fixing plate 251 formed by forming the hexahedron and the four corner regions of one side of the fixing plate 251, for example, the hexahedral shape fixing plate 251, are inserted into and fixed to one side of the first electrode part 241. At least two screw jacks 252, a linkage shaft 253 for providing rotational force to the pair of screw jacks 252, and a gear for shifting the rotational force provided to each linkage shaft 253, respectively. Box 254, a drive motor 255 that provides rotational force to the gear box 254.

For example, the screw jack 252 may be formed of four screw jacks 252 fixedly coupled to four corresponding corners of the first electrode part 241 by inserting four corners of the fixing plate 251. That is, the first electrode part 241 is raised and lowered in cooperation with the rotation of the driving motor 255. Specifically, the drive motor 255 provides a rotational force to the gear box 254, the gear box 254 provides a rotational force to each of the interlocking shaft 253, each of the interlocking shaft 253 is four screw jack ( By providing rotational force to 252, the four screw jacks 252 fix the first electrode portion 241 fixedly coupled to the screw jack 252 in a direction substantially perpendicular to the filter cloth conveyed by the filter cloth conveying portion 220. Elevate. Therefore, the four screw jacks 252 as described above can precisely control the lifting of the first electrode portion 241 to apply substantially the same pressure to the front of the sludge, thereby providing uniform and constant dehydration to the sludge. It can be performed stably and in stages. Here, reference numeral 256 is an insulating member that electrically insulates the first electrode portion 241 and the screw jack 252, and is formed between the first electrode portion 241 and the screw jack 252, respectively.

The controller (not shown) controls the driving unit 250 to precisely adjust the compression height of the first electrode part 241 of the dewatering part 240 to the sludge in accordance with the dewatering rate of the sludge in steps, and Voltage application to the two electrode portions 241 and 242 is controlled. That is, the controller precisely controls the pressing force and the pressurization time for the sludge of the first electrode portion 241 of the dewatering part 240 by the screw jack 252 of the driving part 250 according to the sludge properties or the thickness of the sludge. . In addition, the controller controls voltage application to the first and second electrode portions 241 and 242 of the dehydration unit 240 to form an electric field in the sludge to dewater the sludge. Herein, the controller may remotely control the driver 250 by wire or wirelessly for the convenience of the user.

For example, the controller controls the first electrode part 241 of the dewatering part 240 to correspond to the dewatering amount of the sludge so that the first electrode part 241 is perpendicular to the sludge conveyed by the filter cloth conveying part 220. Is stepped downward to apply the same pressure and voltage.

On the other hand, the height detection unit 260 by counting and counting the rotational speed of the drive shaft 253 or the drive motor 255 to detect the pressing height of the first electrode unit 241, the dehydration unit by the drive unit 250 The height of the crimp with respect to the sludge of the first electrode unit 241 of 240 is sensed. That is, the controller lowers the sludge by a predetermined crimp height of the first electrode part 241 to the sludge, dehydrates the sludge by an electric field applied by voltages applied to the first and second electrode parts 241 and 242, and then dehydrates the sludge. As a result, the sludge is dewatered in a stepwise manner by a predetermined compression height of the first electrode part 241 in response to the sludge having a reduced volume. Here, the control unit adjusts the crimp height of the first electrode part 241 detected by the height detecting unit 260 to gradually step the sludge so as to correspond to the volume of the sludge changed by the dehydration of the first electrode part 241. Lower Therefore, the control unit can easily perform the dehydration reaction control according to the progress of the dehydration reaction of the sludge by gradually lowering the first electrode part 241 in response to the volume of the sludge changed by dehydration. In addition, since the dehydration rate is also different due to the pressurization error of several mm units of the first electrode part 241 with respect to the sludge, the water content of the sludge is greatly changed. Therefore, the height detecting unit 260 is driven by the controller 250. Since it enables precise control of the screw jack 252, it is possible to implement a constant dehydration rate by the dehydration unit 240.

On the other hand, the guide 270 is formed through the fixing plate 251 to be fixed to the first electrode portion 241 and the guide according to the lifting of the first electrode portion 241 of the dewatering portion 240 by the driving unit 250 The apparatus further includes a lift limit detector configured to detect a lift limit of 270.

Here, the lift limit detection unit 280, the limit rising height and the limit falling of the first electrode portion 241, so that the first electrode portion 241 of the dewatering portion 240 can maintain the proper crimp height for the sludge. Detect the height of each. That is, the lift limit detecting unit 280 detects the limit rising height of the first electrode unit 241 to prevent malfunction or damage of the screw jack 252 and detects the limit falling height of the first electrode unit 241. This prevents the pressing force above the limit value against the sludge. For example, when the limit lift height of the first electrode unit 241 is detected by the lift limit detection unit 280, the controller may forcibly stop the driving unit 250 to effectively prevent malfunction or damage of the screw jack 252. Effectively prevents pressing force above the limit value against the sludge. Therefore, the lift limit height of the lift limit detection unit 280 according to the load of the sludge, for example, the property and thickness of the sludge, which is supplied to the sludge supply unit 230 by the controller, is preset and supplied to the sludge supply unit 230. Even if the sludge load, for example, the sludge properties and thickness change, the dehydration rate for the sludge can be kept uniform and constant. Here, reference numeral 281 is a lift limit detector frame 281 that is fixed to the lifting direction of the guide 270 on the fixing plate 251, and is mounted on the lift limit detector 280.

Meanwhile, referring to FIGS. 3A to 3C, the exhaust pipe 290 is fixedly formed on the side surface of the first electrode part 241 of the dewatering part 240, and is formed from sludge dewatered stepwise by the dewatering part 240. Exhaust the wet steam to the outside.

2A and 2B, the ventilation unit 295 is fixed to the frame 210 at a position opposite to the other side of the filter cloth conveying unit 220, for example, the sludge supply unit 230, and the dewatering unit 240. Is supplied with the wet steam generated from the dewatered sludge. That is, the exhaust pipe 290 and the ventilation unit 295 supply the wet steam generated from the sludge and exhaust it to the outside, thereby effectively preventing the corrosion of each component of the electric permeation type sludge reduction apparatus 200 according to the present embodiment. Can be.

The above terms are terms set in consideration of functions in the present invention, which may vary depending on the intention or custom of the producer, and the definitions should be made based on the contents throughout the specification. In addition, in the following description of the embodiment of the present invention with reference to the accompanying drawings has been described for the electro-penetrating sludge reduction apparatus having a specific shape and structure, the present invention can be variously modified and changed by those skilled in the art, such a modification And modifications should be construed as falling within the protection scope of the present invention.

200: electric penetration sludge reduction device 210: frame
220: filter cloth conveying unit 221: filter cloth
222: driving roller 223: end roller
224: guide roller 225: drive motor
226: tension roller 230: sludge supply unit
231: hopper 231-1: sludge inlet
231-2: Sludge outlet 232: Sludge supply amount sensor
233: sludge feed roller 240: dewatering part
241: First electrode part 241-1: First electrode plate
241-3: voltage terminal 241-4: conductive member
241-5: reinforcing member 241-5a: horizontal reinforcing piece
241-5b: vertical reinforcing piece 242: second electrode portion
250: drive unit 251: fixed plate
252: screw jack 253: interlocking shaft
254: gear box 255: drive motor
256: insulation member 260: height detection unit
270 guide 280 lifting limit detection unit
281: lift limit detection unit frame 290: exhaust pipe
295: ventilation unit 1100: frame
1600: filter cloth 1700: sludge lifting means

Claims (8)

A frame of a certain shape,
It is formed in the longitudinal direction of the frame, the filter cloth conveying portion for rotating the filter cloth infinitely,
A sludge supply unit formed at one side of the filter cloth conveying unit and supplying sludge to the upper part of the filter cloth;
And a first electrode portion formed on the upper side of the filter cloth conveyed to the filter cloth conveying portion, and a second electrode portion formed on the lower side of the filter cloth to face the first electrode portion. A dewatering part for dewatering the sludge by compressing the sludge supplied to the filter cloth conveying part and applying an electric voltage to form an electric field;
A driving part fixedly formed on the frame at an upper side of the dewatering part, and elevating the dewatering part;
The control unit for controlling the driving unit to adjust the height of the dehydration portion to the sludge, and to control the voltage applied to the first and second electrode portion,
The dewatering portion is dewatered by substantially the same pressure and voltage of the sludge supplied to the filter cloth conveying portion,
And the control unit controls the first electrode part of the dewatering part to gradually lower the first electrode part in the sludge direction to apply the same pressure and voltage in response to the dewatering amount of the sludge. delete The method according to claim 1,
The first electrode unit,
A first electrode plate that applies substantially the same pressure and voltage to the sludge, a voltage terminal arranged to be uniformly spaced above the first electrode plate and applying a voltage to the first electrode plate, and a voltage to the voltage terminal It is made of a conductive member that conducts
And the first electrode part further comprises a reinforcing member for reinforcing and supporting the first electrode plate. delete The method according to claim 1,
Comprising the rotational speed of the drive shaft or the drive motor to detect the pressing height of the first electrode portion, and further comprising a height sensing unit for detecting the pressing height of the sludge of the first electrode portion of the dewatering portion by the drive unit Electro-permeable sludge reduction device characterized in that. The method according to claim 1,
A guide formed through the fixing plate to be fixed to the first electrode;
And a lift limit detection unit for detecting a lift limit of the guide according to the lift of the first electrode of the dehydration unit by the driving unit. The method according to claim 1,
And an exhaust pipe fixed to the first electrode portion of the dewatering portion and configured to exhaust the wet steam generated from the sludge dewatered stepwise by the dewatering portion. The method according to claim 1,
And a ventilation part fixedly formed on the frame at the other side of the filter cloth conveying part and supplying the wet steam generated from the sludge dehydrated by the dehydration part.

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