KR20130011540A - Dehydrator - Google Patents

Abstract

PURPOSE: An electroosmotic dehydrator is provided for a voltage applied according to the dehydration progress passage of a sludge when it rises gradually or when the voltage is descended improving the dewatering efficiency. CONSTITUTION: An electroosmotic dehydrator comprises of a dehydration belt(30), a caterpillar part and a drum part. The drum part has drums(50,60) which are rotatably arranged in the frame and the caterpillar part has the caterpillar(70) installed separately in the drum. The dehydration belt dehydrates sludge while the dehydration belt is transferred between the drum and the caterpillar. The total number of caterpillar and drum may be 3 or more. In terms of the drum and caterpillar, the forward movement is permitted through an electric potential difference by successively enhancing or decreasing to the travelling route of the dehydration belt. A gradation power is also equipped.

Description

Electropenetrating dehydrator

The present invention relates to a dewatering device, and more particularly, to an electroosmotic dewatering device which can improve the dewatering efficiency of sludge.

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 filter belt formed to overlap the surface.

Korean Patent Application No. 1993-0010856 discloses an electro-permeable sludge dewatering device.

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.

However, this dewatering structure has a disadvantage in that the dewatering efficiency is limited to a certain range by not considering the variation of the water content according to the passage of the sludge.

The present invention was devised to improve the above problems, and an object of the present invention is to provide an electropenetrating dehydrator capable of improving the dehydration efficiency by varying the voltage applied according to the water content which varies along the dewatering path of the sludge.

In order to achieve the above object, the electropenetrating dehydrator according to the present invention is a drum unit having a drum rotatably installed on a frame, a caterpillar unit having a caterpillar spaced apart from the drum, and transported between the drum and the caterpillar. In the electro-osmotic dehydrator having a dewatering belt for dewatering the sludge while the total number of the drum and the caterpillar is provided three or more, the potential difference in sequence along the traveling path of the dewatering belt for the drum and the caterpillar It is provided with a; differential power applying unit for applying a potential to be higher or lower.

According to an aspect of the present invention, the drum unit includes a first drum and a second drum sequentially spaced apart on a traveling path of the dewatering belt, and the caterpillar unit includes both the first drum and the second drum. A first caterpillar provided to be circulated and rotated via the first caterpillar, wherein the differential power applying unit comprises: a first power applying unit for applying a first potential to the first caterpillar and the first drum; And a second power supply unit configured to apply a second potential higher or lower than the first potential to the first caterpillar and the second drum.

According to another aspect of the present invention, the drum unit has a first drum provided on the traveling path of the dewatering belt, the caterpillar unit and the first caterpillar installed to be rotated to face a portion of the outer peripheral surface of the first drum; ; And a second caterpillar installed to be circulatedly rotated to face a portion of an outer circumferential surface of the first drum so as to press the dewatering belt through the first caterpillar to the first drum. A first power supply unit for applying a first potential to the first caterpillar and the first drum; And a second power supply unit configured to apply a second potential higher or lower than the first potential to the second caterpillar and the first drum.

According to another aspect of the invention, the drum portion has a first drum and a second drum disposed sequentially spaced on the traveling path of the dewatering belt, the caterpillar portion facing a portion of the outer peripheral surface of the first drum A first caterpillar installed to be circulatedly rotated; A second caterpillar installed to be circulatedly rotated to face a portion of an outer circumferential surface of the first drum so as to press the dewatering belt via the first caterpillar to the first drum; A third caterpillar installed to be circulatedly rotated to face a portion of an outer circumferential surface of the second drum to press the dewatering belt entering the second drum via the first drum to the second drum; And a fourth caterpillar installed to be circulatedly rotated to face a portion of an outer circumferential surface of the second drum so as to press the dewatering belt via the third caterpillar to the second drum. A first power supply unit for applying a first potential to the first caterpillar and the first drum; A second power supply unit configured to apply a second potential higher or lower than the first potential to the second caterpillar and the first drum; A third power supply unit applying a third potential higher or lower than a second potential to the third caterpillar and the second drum; And a fourth power applying unit configured to apply a fourth potential higher or lower than the third potential to the fourth caterpillar and the second drum.

According to the electropenetrating dehydrator according to the present invention, the voltage applied according to the progress of dehydration of the sludge may be gradually raised or lowered according to the sludge property to further improve the dehydration efficiency.

1 is a side view schematically showing an electropenetrating dehydrator according to a first embodiment of the present invention,
FIG. 2 is a perspective view showing an extract of a portion around the first drum of FIG. 1;
3 is a view showing a differential power applying unit for applying power to the drum and the caterpillar of FIG.
4 is a view schematically showing an electropenetrating dehydrator according to a second embodiment of the present invention,
5 is a view schematically showing an electropenetrating dehydrator according to a third embodiment of the present invention.

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

FIG. 1 is a side view schematically showing an electropenetrating dehydrator according to a first embodiment of the present invention, FIG. 2 is a perspective view showing a portion around a first drum of FIG. 1, and FIG. 3 is a drum of FIG. 1. Figure is a diagram showing a differential power applying unit for applying power to the caterpillar.

1 to 3, the electro-osmotic dehydrator 10 moves along the first trajectory while moving the introduced sludge, and the traveling direction of the dewatering belt 30 and the dewatering belt 30. Along the first and second drums 50 and 60 and the first and second drums 50 and 60 spaced apart from each other along the second track, One caterpillar 70 is provided.

When the electroosmotic dehydrator 10 is provided with a total number of three or more of the sum of the drums 50 and 60 and the caterpillar 70 so as to apply different potentials along the traveling path of the dewatering belt 30, do.

Although not shown, a conveying belt may be further provided to convey the sludge introduced through the hopper to the dewatering belt.

The rest of the structure of the electroosmotic dehydration apparatus 10 is known in various ways, such as Korean Patent Application No. 2007-0098334 filed by the present applicant, and detailed description thereof will be omitted.

The first drum 50, the second drum 60, and the first caterpillar 70, which are rotatably installed in the frame 20, are formed of a conductive material to function as an electrode body, and the first and second drums. It can be constructed to apply an electric potential through the rotating shaft (51) 61 of the (50) (60) and the roller (72) provided on the circulation trajectory of the first caterpillar (70).

The first drum 50 and the second drum 60 applied to the drum are sequentially arranged to be spaced apart along the traveling path of the dewatering belt 30.

In this case, the sludge may be constructed such that the sludge can be introduced on the transport path of the dewatering belt 30 before passing through the first drum 50.

The first caterpillar 70 applied to the caterpillar unit is circulated and rotated via both the first drum 50 and the second drum 60.

In such a structure, the differential power applying unit may directly increase or decrease the DC power so that the first and second drums 50 and 60 and the first caterpillar 70 may be sequentially increased or decreased depending on the properties of the sludge along the traveling path of the dewatering belt 30. The potential is applied.

Here, the property of the sludge is determined by the type of sludge and the electrical conductivity.

As an example, in the case of microbial sludge, the water of the sludge may be classified into an inner water surrounded by the cell membrane of the microorganism and an external water contained between the cell membranes. Dislocations are sequentially applied to the first and second drums 50 and 60 and the first caterpillar 70 along the traveling path of the dewatering belt 30.

On the contrary, when the content of the internal water of the sludge is greater than the external water, the differential power applying unit dewateres the belt 30 with respect to the first and second drums 50 and 60 and the first caterpillar 70 to destroy the cell membrane first. It is constructed to apply the potential to be sequentially lowered along the progress path of).

In addition, when the electrical conductivity of the sludge is higher than the set reference value, the differential power applying unit is sequentially increased along the traveling path of the dewatering belt 30 with respect to the first and second drums 50, 60 and the first caterpillar 70. When the electrical conductivity of the sludge is lower than the set reference value, the differential power applying unit is configured to determine the traveling path of the dewatering belt 30 with respect to the first and second drums 50 and 60 and the first caterpillar 70. Therefore, it is constructed to apply the potential to be lowered sequentially.

The differential power supply unit includes a first power supply unit 81 and a second power supply unit 82.

The first power applying unit 81 applies a first potential to the first caterpillar 70 and the first drum 50.

The second power supply unit 82 applies a second potential higher or lower than the first potential to the first caterpillar 70 and the second drum 60.

In the illustrated example, a positive potential corresponding to the first potential is applied to the first drum 50 using the first caterpillar 70 as a common terminal, and a second potential higher than the first potential to the second drum 60. It is wired to apply.

Preferably, when the second potential is set higher than the first potential according to the properties of the sludge described above, the first potential may be configured to apply 50 to 70 volts and the second potential to 71 to 85 volts. In addition, when the second potential is set lower than the first potential according to the properties of the sludge described above, the first potential may be configured to apply 71 to 85 volts, and the second potential may be applied to 50 to 70 volts.

Unlike this, as illustrated in FIG. 4, the drum unit is applied with a first drum 50 on the traveling path of the dewatering belt 30, and the caterpillar unit is circulated to face a part of the outer circumferential surface of the first drum 50. The first caterpillar 170 is rotated and the first caterpillar 170 in a position spaced apart from the first caterpillar 170 to press the dewatering belt 30 via the first caterpillar 170 to the first drum 50. A structure having a second caterpillar 175 installed to be circulatedly rotated to face a portion of the outer circumferential surface of the drum 50 may be applied. In order to avoid the complexity of the drawing, only one of the rotating rollers 172 circulating the first caterpillar 170 has been given a reference numeral.

In this case, the differential power supply unit is applied to the first power supply unit 181 for applying the first potential to the first caterpillar 170 and the first drum 50, and to the second caterpillar 175 and the first drum 50. The second power supply unit 182 that applies a second potential higher or lower than the first potential may be applied.

In the illustrated example, a positive potential corresponding to the first potential is applied to the first caterpillar 170 using the first drum 50 as a common terminal, and a second potential higher than the first potential to the second caterpillar 175. It is wired to apply.

Unlike the illustrated example, a positive potential corresponding to the second potential is applied between the first drum 50 and the second caterpillar 175 so that a positive potential is applied to the first drum 50, and the first drum Of course, the second potential may be divided between 50 and the first caterpillar 170, and the first potential lower than the second potential may be constructed to be applied to the first caterpillar 170.

Meanwhile, a positive potential corresponding to the first potential is applied to the first caterpillar 170 using the first drum 50 as a common terminal, and a second potential lower than the first potential is applied to the second caterpillar 175. Of course, the wiring can be made to.

Alternatively, as shown in FIG. 5, the drum unit includes a first drum 50 and a second drum 60 sequentially spaced apart on a traveling path of the dewatering belt 30, and the caterpillar unit includes a first drum. The first caterpillar 270 and the dewatering belt 30 passing through the first caterpillar 270 and the first caterpillar 270 installed to be circulatedly rotated to face a portion of the outer circumferential surface of the first body 50 are spaced apart from the first caterpillar 270. The second caterpillar 275 and the second caterpillar 275 which are installed to be circulated and rotated to face a part of the outer circumferential surface of the first drum 50 so as to pressurize the drum 50, and to the second drum 60 via the first drum 50. A third caterpillar 277 and a third caterpillar 277 installed to be circulatedly rotated to face a part of the outer circumferential surface of the second drum 60 so as to press the dewatering belt 30 into the second drum 60. A fourth caterpillar installed to be circulatedly rotated to face a part of the outer circumferential surface of the second drum 60 so as to press the dewatering belt 30 via the second drum 60 ( 279) can be applied.

In this case, the differential power applying unit includes the first to fourth power applying units 281 to 284, and as described above, the first to fourth power applying units 281 to 284 sequentially change potentials according to the properties of the sludge. Is constructed to gradually rise, or the potential is sequentially constructed to fall, and the illustrated example illustrates a structure in which the potential is sequentially raised to avoid the complexity of explanation.

The first power applying unit 281 applies a first potential to the first caterpillar 270 and the first drum 50.

The second power supply unit 282 applies a second potential higher or lower than the first potential to the second caterpillar 275 and the first drum 50.

The third power applying unit 283 applies a third potential higher or lower than the second potential to the third caterpillar 277 and the second drum 60.

The fourth power applying unit 284 applies a fourth potential higher or lower than the third potential to the fourth caterpillar 279 and the second drum 60.

Here, the first potential, the second potential, the third potential, and the fourth potential are applied to be sequentially increased or sequentially lowered as described above.

In this way, if the potential is gradually increased or decreased depending on the properties of the sludge between the drum and the caterpillar applying the potential along the traveling path of the dewatering belt 30, according to the transfer of the dewatering belt 30 in the electric dehydration process. The dewatering efficiency of the sludge can be further increased.

10: electrofiltration dehydrator 30: dewatering belt
50: first drum 60: second drum

Claims (4)

An electric permeation dehydrator comprising a drum part having a drum rotatably installed on a frame, a caterpillar part having a caterpillar spaced apart from the drum, and a dewatering belt for dewatering sludge while being transported between the drum and the caterpillar. ,
The total number of the drum and the caterpillar is provided with three or more, and the differential power applying unit for applying the potential to increase or decrease the potential difference sequentially along the traveling path of the dewatering belt to the drum and the caterpillar; Electroporation dehydrator, characterized in that. The drum of claim 1, wherein the drum unit comprises a first drum and a second drum sequentially spaced apart from each other on a traveling path of the dewatering belt.
The caterpillar unit includes a first caterpillar installed to be circulatedly rotated through both the first drum and the second drum.
The differential power applying unit
A first power supply unit applying a first potential to the first caterpillar and the first drum;
And a second power supply unit for applying a second potential higher or lower than the first potential to the first caterpillar and the second drum. According to claim 1, wherein the drum unit has a first drum provided on the traveling path of the dewatering belt,
The caterpillar part
A first caterpillar installed to be circulatedly rotated to face a portion of an outer circumferential surface of the first drum;
And a second caterpillar installed to be circulatedly rotated to face a portion of an outer circumferential surface of the first drum so as to press the dewatering belt via the first caterpillar to the first drum.
The differential power applying unit
A first power supply unit applying a first potential to the first caterpillar and the first drum;
And a second power supply unit configured to apply a second potential higher or lower than the first potential to the second caterpillar and the first drum. The drum of claim 1, wherein the drum unit comprises a first drum and a second drum sequentially spaced apart from each other on a traveling path of the dewatering belt.
The caterpillar part
A first caterpillar installed to be circulatedly rotated to face a portion of an outer circumferential surface of the first drum;
A second caterpillar installed to be circulatedly rotated to face a portion of an outer circumferential surface of the first drum so as to press the dewatering belt via the first caterpillar to the first drum;
A third caterpillar installed to be circulatedly rotated to face a portion of an outer circumferential surface of the second drum to press the dewatering belt entering the second drum via the first drum to the second drum;
And a fourth caterpillar installed to be circulatedly rotated to face a portion of an outer circumferential surface of the second drum so as to press the dewatering belt via the third caterpillar to the second drum.
The differential power applying unit
A first power supply unit applying a first potential to the first caterpillar and the first drum;
A second power supply unit configured to apply a second potential higher or lower than the first potential to the second caterpillar and the first drum;
A third power supply unit applying a third potential higher or lower than a second potential to the third caterpillar and the second drum;
And a fourth power applying unit configured to apply a fourth potential higher or lower than the third potential to the fourth caterpillar and the second drum.

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