KR101240618B1 - dehydrator - Google Patents

Abstract

The present invention relates to an electropenetrating dehydration apparatus for dewatering sludge conveyed between a first electrode body and a second electrode body by a voltage difference applied through a first electrode body and a second electrode body which are installed to face each other. The pulse generator for generating a pulse voltage from the three-phase AC power supply through the electrodes provided in the first electrode body and the second electrode body, the first coil portion connected between the R-phase supply line and the S-phase supply line of the three-phase AC power source, A second coil part of which one end is connected in the middle of the first coil part and the other end of which is connected to the T-phase supply line, a third coil part which outputs electromotive force coupled with the first coil part, and a second coil part Is coupled between the fourth coil part connected in series with one end of the third coil part and the other end not connected with the third coil part of the third coil part and the fourth coil part which are coupled to and output the induced electromotive force. The first and second A rectifier for outputting a pulse flow to the first electrode body and the second electrode body through the two output terminal. According to the electro-osmotic dehydration device, a pulse current can be generated directly from the three-phase AC power supply and supplied to the drum and the caterpillar, thereby providing the advantage that the drum and the caterpillar do not have to be formed in an electrode split structure.

Electro Infiltration Dehydrator, Pulse

Description

High Efficiency Electropenetration Dehydrator

The present invention relates to a dewatering device, and more particularly to an electroosmotic dewatering device having an improved pulse generation structure.

In general, sludge (sludge) generated in wastewater and sewage treatment plants uses a polymer flocculant to purify water, and sludge aggregated by the polymer flocculant is difficult to dehydrate. According to the sludge dewatering rate, there is a big difference in sludge disposal cost and recycling range. Also, if the water content of sludge can be significantly reduced, not only the waste cost is reduced but also the solid components of the sludge are fueled. It is also very economically added value, such as being able to recycle into a furnace. However, the conventional simple pressurized dewatering device has a limitation in the dewatering of the wastewater sludge, so in recent years, an electropenetrating dewatering device having good dewatering efficiency for dewatering the sludge has been utilized.

The electro-osmotic dewatering device is to remove the sludge-related water by ion mobility. It is a rotating drum which serves as an anode electrode, a water-permeable compression belt formed to surround the outer circumferential surface of the rotating drum, and a dewatering area of the rotating drum and the pressing belt. It consists of a filtration belt formed to overlap the surface.

Japanese Patent Application Laid-Open No. 56-60604 and Korean Patent Application No. 1993-0010856 disclose an electroosmotic sludge dewatering apparatus.

The disclosed electro-osmotic sludge dewatering device forms an electric field by applying a constant voltage between the drum and the pressing belt so that the charged water in the electric field moves to the electrode opposite to the charge carried by the sludge particles by electrophoresis and capillary action. As it is separated, dehydration is carried out from the sludge.

On the other hand, in recent years, three-phase alternating current is rectified for each phase (R, S, T) so that a voltage drop does not occur, and then converted into a DC voltage pulse. An electropenetrating dewatering dehydration device which prevents losses from occurring and also maintains a constant voltage at all times to increase dewatering performance has been proposed by the applicant of 10-2005-0108803 filed by the present applicant.

However, in the case of rectifying the three-phase AC power source, the electrodes or the belt should be divided into structures to receive the rectified voltages for the respective phases. In this case, the structure becomes complicated.

SUMMARY OF THE INVENTION The present invention has been made to solve the above requirements, and an object thereof is to provide an electropenetrating dehydration apparatus capable of generating and supplying a pulse current voltage from a three-phase alternating current power supply so as to alleviate the restrictions on electrode division.

In order to achieve the above object, the electroosmotic dehydration apparatus according to the present invention is transferred between the first electrode body and the second electrode body by a voltage difference applied through the first electrode body and the second electrode body which are installed to face each other. In the electric permeation dewatering device for performing the dewatering of the sludge, a pulse current generating unit for generating a pulse current voltage from the three-phase AC power supply through the electrodes provided in the first electrode body and the second electrode body; The pulse generating unit comprises: a first coil part connected between the R-phase supply line and the S-phase supply line of the three-phase AC power source; A second coil part of which one end is connected in the middle of the first coil part and the other end thereof is connected to a T-phase supply line; A third coil part coupled to the first coil part to output the induced electromotive force; A fourth coil part coupled to the second coil part to output the induced electromotive force and connected in series with one end of the third coil part; And a rectifying part connected between the other end of the third coil part and the other end not connected to the third coil part of the fourth coil part to rectify the induced voltage and output the first voltage through the first and second output terminals. An electrode of the first electrode body is connected to the first output terminal and an electrode of the second electrode body is connected to the second output terminal.

According to an aspect of the present invention, the rectifier is applied between the other end of the third coil portion and the other end of the fourth coil portion is connected to the other end which is not connected to the third coil portion is applied to the full-wave rectifier do.

According to another aspect of the present invention, the rectifying portion is connected between the other end of the third coil portion and the other end not connected to the third coil portion of the fourth coil portion is switched on / off in accordance with a control signal And a controller configured to selectively rectify the voltage, and to control on / off of the switch elements.

The rectifying unit includes: a first esal connected forward between the other end of the third coil unit and the first output end; A second esr connected forward between the other end of the fourth coil portion and the first output end; A third esr connected backward between the other end of the third coil portion and the second output end; And a fourth esal connected in a reverse direction between the other end of the fourth coil portion and the second output end, and an operation unit capable of setting selective driving of the first to fourth esials. The switch may be configured to switch on / off the first to fourth SALs according to the driving pattern set by the operation unit.

According to the electroosmotic dehydration apparatus according to the present invention, it is possible to generate a pulse current voltage directly from a three-phase AC power supply and supply it to the drum and the caterpillar, thereby providing the advantage that the drum and the caterpillar do not have to be formed in an electrode split structure.

Hereinafter, with reference to the accompanying drawings will be described in more detail an electroosmotic dewatering apparatus according to a preferred embodiment of the present invention.

1 is a perspective view showing an example of an electroosmotic dewatering device according to the present invention.

Referring to FIG. 1, the dewatering device 10 includes a pressurizing belt 40 for pressurizing and transporting sludge that is infinitely moved by a plurality of rollers and a pressurized belt 40 disposed to face each other on a conveying path of the pressurizing belt 40. The first electrode body 50 and the second electrode body 60 are provided.

The electro-osmotic dewatering device 10 is known in various ways, such as domestic patent application No. 2007-0098334 filed by the present applicant, detailed description thereof will be omitted.

Meanwhile, although the first electrode body 50 is formed in a drum shape and the second electrode body 60 is formed of a caterpillar, the first electrode body 50 and the second electrode body 60 may generate pulses described later. What is necessary is just to be formed in the form which can dehydrate from the sludge conveyed by the potential difference applied from the part 100, Of course, it is not limited to the form shown.

Hereinafter, the first electrode body 50 and the second electrode body 60 will be described with an equivalent circuit system.

2 is a circuit diagram showing a pulse flow generating unit according to the present invention.

Referring to FIG. 2, the pulse generation generator 100 generates a single-phase pulse voltage from a three-phase alternating current power source, and thus, through the first output terminal 131 and the second output terminal 132, the first electrode body 50 and the second electrode. It is applied through the electrodes 51 and 61 provided in the electrode body 60. In the illustrated example, the first electrode body 50 has an electrode 51 formed on the outer circumferential surface of the drum to be electrically connected to the first output terminal 131, and the second electrode body 60 circulates in an endless track in the form of a caterpillar. A conductive roller which is rotated in contact with the second electrode body 60 to guide the circulation of the second electrode body 60 formed of a conductive material is applied to the electrode 61 of the second electrode body 60. The structures and shapes of the electrodes 51 and 52 of the first electrode body 50 and the second electrode body 60 may be applied differently from the illustrated examples.

The pulse generating unit 100 includes first to fourth coil parts 111 to 114 and first to fourth diodes 121 to 124.

The first coil part 111 is connected between the R-phase supply line 101 and the S-phase supply line 102 of the three-phase AC power source, and one end of the second coil part 112 is in the middle of the first coil part 111. The other end is connected to the T-phase supply line 103.

In addition, the third coil part 113 is coupled to the first coil part 111 and outputs the electromotive force, and the fourth coil part 114 is coupled to the second coil part 112 and induced. Outputs

Here, one end 114a of the fourth coil part 114 is connected in series with one end 113a of the third coil part 113.

The first to fourth diodes 121 to 124 carry out full-wave rectification of voltages induced at both ends of the third coil part 113 and the fourth coil part 114 connected in series, so that the first and second output terminals 131 ( 132 is applied as a full-wave rectifier for outputting the pulse flow.

The first diode 121 is forwardly connected between the other end 113b of the third coil part 113 and the first output end 131, and the second diode 122 is connected to the other end of the fourth coil part 114. 114b) and the 1st output terminal 131 are forward-connected.

The third diode 123 is reversely connected between the other end 113b of the third coil part 113 and the second output end 132, and the fourth diode 124 is connected to the other end of the fourth coil part 114. 114b) and the second output terminal 132 are connected in the reverse direction.

The voltage output through the first output terminal 131 and the second output terminal 132 of the pulse generating unit 100 generates a pulse voltage as shown in FIG. 3.

Here, the first output terminal 131 is connected to the electrode 51 of the first electrode body 50, and the second output terminal 132 is connected to the electrode 61 of the second electrode body 60.

In the electro-osmotic dewatering device 10 to which the pulse generating unit 100 is applied, a single-phase pulse voltage is generated by the pulse generating unit 100 from a three-phase AC power source so that the first electrode body 50 and the second electrode body ( 60, the sludge conveyed between the first electrode body 50 and the second electrode body 60 is dehydrated by the method described above.

On the other hand, unlike the illustrated example, a structure that can be generated in a desired pattern without continuously generating a pulse flow is shown in FIG. The same elements as in the previous drawings are denoted by the same reference numerals.

Referring to FIG. 4, the rectified part is connected between the other end of the third coil part and the other end not connected to the third coil part of the fourth coil part, and is switched on / off according to a control signal of the controller 220 to be induced. It is provided with a first to fourth escral (SCR) which is a switch element to selectively rectify the.

The first SCR 221 is forwardly connected between the other end 113b of the third coil part 113 and the first output end 131, and the second SCR 222 is the fourth. A forward connection is made between the other end 114b of the coil part 114 and the first output end 131.

The third esr (SCR) 223 is connected in a reverse direction between the other end 113b of the third coil part 113 and the second output end 132, and the fourth esr (SCR) 224 is the fourth. A reverse connection is made between the other end 114b of the coil part 114 and the second output end 132.

The operation unit 230 is configured to set the selective driving of the first to fourth SALs 221 to 224.

The controller 220 controls the first to fourth SSIs 221 to 224 to be switched on / off according to the driving pattern set by the operation unit 230.

In this case, the controller 220 may generate waveforms of various patterns by the switch on / off control of the first to fourth SALs 221 to 224. For example, as shown in FIG. It is possible to form a pattern that occurs intermittently missing.

Meanwhile, in the illustrated example, four esials 221 to 224 are applied between the other end 113b of the third coil part 113 and the other end 114b of the fourth coil part 114. Alternatively, the first esal 221 and the second esal 222 may be applied as it is, and the third and fourth esal 223 and 224 may be replaced by the third and fourth diodes.

1 is a perspective view showing an example of the electric penetration dehydration apparatus according to the present invention,

2 is a circuit diagram showing a pulse flow generating unit according to an embodiment of the present invention,

FIG. 3 is a waveform diagram of pulse voltages output through the first and second output terminals of FIG. 2;

4 is a circuit diagram showing a pulse flow generating unit according to another embodiment of the present invention;

FIG. 5 is a waveform diagram illustrating an example of pulse voltages output through the first and second output terminals of FIG. 3.

Claims (4)

In the electro-osmotic dewatering apparatus for performing the dehydration of the sludge transferred between the first electrode body and the second electrode body by the voltage difference applied through the first electrode body and the second electrode body which are installed opposite to each other, And a pulse current generating unit generating a pulse voltage from a three-phase AC power supply and applying the same through an electrode provided in the first electrode body and the second electrode body. The pulse flow generating unit A first coil part connected between the R-phase supply line and the S-phase supply line of the three-phase AC power source; A second coil part of which one end is connected in the middle of the first coil part and the other end thereof is connected to a T-phase supply line; A third coil part coupled to the first coil part to output the induced electromotive force; A fourth coil part coupled to the second coil part to output the induced electromotive force and connected in series with one end of the third coil part; The first and second output terminals are rectified by rectifying the induced voltage connected between the other end of the third coil part not connected to the fourth coil part and the other end not connected to the third coil part of the fourth coil part. And a rectifying unit output through the And an electrode of the first electrode body is connected to the first output terminal, and an electrode of the second electrode body is connected to the second output terminal. The rectifying part of claim 1, wherein the rectifying part is a full-wave rectifying part connected between the other end of the third coil part and the other end not connected to the third coil part of the fourth coil part to full-wave rectify the induced voltage. Electric penetration dewatering device. The rectifier of claim 1, wherein the rectifier is connected between the other end of the third coil part and the other end not connected to the third coil part of the fourth coil part to switch on / off the induced voltage according to a control signal. It is provided with a plurality of switch elements that can be selectively rectified, And a controller for controlling on / off of the switch elements. The method of claim 3, wherein the rectifying unit A first esal connected forward between the other end of the third coil portion and the first output end; A second esr connected forward between the other end of the fourth coil portion and the first output end; A third esr connected backward between the other end of the third coil portion and the second output end; And a fourth esr connected backward between the other end of the fourth coil portion and the second output end. And an operation unit capable of setting selective driving of the first to fourth sushi. And the controller is configured to switch on / off the first to fourth SSIs according to a driving pattern set by the operation unit.

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