KR101972575B1 - Sludge feeder for drum-type thickener - Google Patents

Abstract

According to the present invention, provided is an apparatus for equally supplying a sludge of a drum concentrator, which is installed in a drum concentrator including a cylindrical screen provided to separate a filtrate from a sludge while rotating around a rotary shaft to horizontally extend by having the sludge on a surface thereof. The apparatus of the present invention comprises: a sludge chamber provided to receive a sludge from the outside, installed adjacent to a cylindrical screen, and having a front surface as an open surface to allow the supplied sludge to be in contact with a surface of the cylindrical screen; a rotary shaft having left and right ends rotatably coupled to left and right side surfaces of the sludge chamber, and rotated in a direction opposite to the cylindrical screen; and a plurality of supply blades fixed to an outer surface of the rotary shaft to be arranged in a rotary direction of the rotary shaft while taking a posture extending from the left end to the right end of the rotary shaft, and pushing the sludge in the sludge chamber to place the same on the surface of the cylindrical screen while passing through a point spaced apart from the surface of the cylindrical screen when the rotary shaft is rotated.

Description

Technical Field [0001] The present invention relates to a sludge feeder for a drum concentrator,

More particularly, the present invention relates to a sludge leveling device capable of uniformly supplying sludge to the surface of a cylindrical screen.

Sewage that is thrown away at home or factory is sent to sewage treatment plant and is processed. The sewage treatment process includes a purification process and a sludge treatment process. In the purification process, the sewage is purified to a range where the self-purification of the river can be activated and discharged to a public water such as a river. In the sludge treatment process, The sludge is treated through processes such as concentration and dehydration.

The concentrator used in the concentration process of the sludge is a device that primarily removes the filtrate from the sludge to be dewatered in a subsequent process. Currently, a drum concentrator is known as a type of the concentrator.

The drum concentrator includes a hollow cylindrical screen as disclosed in Patent No. 10-1131474 (Sludge Concentrator). The cylindrical screen is provided so as to be rotatable and has filtrate discharge holes on its surface. Such a cylindrical screen continues to slowly rotate in one direction during the concentration process.

A sludge feeder is installed on one side of the cylindrical screen. The sludge supply device is provided with a sludge chamber for receiving and containing sludge to be concentrated. The sludge contained in the sludge chamber moves on the surface of the rotating cylindrical screen and is scraped off by the scraper to separate from the surface of the cylindrical screen and the filtrate in which the sludge is faded is removed from the surface of the cylindrical screen while the sludge is moving on the surface of the cylindrical screen And drops through the filtrate discharge holes.

The above drum concentrator is also disclosed in Patent No. 10-0781315 (gravity type preliminary dewatering apparatus with improved dewatering performance), Patent No. 10-1258811 (punch type thickener) and Patent No. 10-1183555 (drum type sludge thickener) .

Patent No. 10-1131474 (sludge thickener) Patent No. 10-0781315 (gravity type preliminary dewatering device with improved dewatering performance) Patent No. 10-1258811 (pore-forming concentrator) 10-1183555 (drum type sludge thickener)

However, in the above-mentioned prior arts, the sludge near both ends of the cylindrical screen is accumulated at the corner of the sludge chamber and can not be laid on the surface of the cylindrical screen, and only the sludge in the middle portion of the cylindrical screen is placed on the cylindrical screen and concentrated A phenomenon is occurring.

This phenomenon is caused by the fact that both sides of the cylindrical screen are not used for the concentration of the sludge, and thus the concentration efficiency is lowered.

In addition, the concentrated sludge separated into the surface of the cylindrical screen may directly fall into the filter cloth of a dehydrator (for example, a belt press) used in the subsequent dehydration process. In this case, concentrated sludge is not distributed on both sides of the filter cloth, The problem is that the middle portion of the filter cloth is concentrated and the dehydration efficiency is lowered.

SUMMARY OF THE INVENTION Accordingly, the present invention provides a sludge leveling device provided in a drum concentrator for uniformly placing sludge on a surface of a cylindrical screen.

The present invention provides an apparatus for supplying sludge in a drum concentrator installed in a drum concentrator including a cylindrical screen, which is disposed to separate sludge from a sludge while rotating around a rotation axis extending in the left-right direction while placing sludge on a surface thereof. And the sludge equalization apparatus comprises a sludge chamber provided to receive sludge from the outside and installed adjacent to the cylindrical screen, the sludge chamber having an open front side to allow the supplied sludge to contact the surface of the cylindrical screen; A rotating shaft having left and right ends rotatably coupled to the left and right sides of the sludge chamber, the rotating shaft being operative to rotate in a direction opposite to the cylindrical screen; And a rotating shaft which is fixed to an outer surface of the rotating shaft so as to be arranged along the rotating direction of the rotating shaft while being in a posture extending from a left end to a right end of the rotating shaft and passes through a point spaced from the surface of the cylindrical screen when the rotating shaft rotates And a plurality of supply blades for pushing the sludge in the sludge chamber and placing the sludge on the surface of the cylindrical screen.

The inclined blades are fixed to the spacing spaces separated by the supply blades and arranged in the rotational direction of the rotating shaft. At least one left-side inclined blade having a slope pushing the sludge to the left is fixed to each of the spaced-apart spaces located on the left side of the center of the rotating shaft, and a sludge is disposed on the right side of each of the spaced- At least one right-side inclined blade having a pushing inclination is fixed.

The left and right tilting blades each have a head and a tail abutting on the line-following supply blades, respectively, which are made at the time of rotation of the rotating shaft. The tail is located farther from the center of the rotating shaft than the head.

The rotating shaft operates to rotate faster than the cylindrical screen.

A sprocket provided at one end of the rotating shaft forms a driven sprocket and a spur gear spouting outside the sludge chamber. The driven sprocket is connected to a driving scroll rocker provided at one end of a rotary shaft of the cylindrical screen through a chain.

According to the present invention, since the supply blade pushes the sludge to the surface of the cylindrical screen over the entire width of the sludge chamber, even the sludge located near the left and right side plates of the sludge chamber can be evenly supplied have.

Further, according to the present invention, the sludge is uniformly supplied to the right and left of the cylindrical screen because the sludge in the sludge chamber spreads to the left and right by the inclined blades while being pulled by the supply blade throughout the rotation of the rotating shaft.

Further, according to the present invention, a motor for rotating the cylindrical screen can be rotated to the rotating shaft.

FIG. 1 is a side view showing a state in which a sludge equalizing device of the drum concentrator according to the present invention is installed.
FIG. 2 is a perspective view showing a sludge-equivalent supply device of the drum concentrator shown in FIG. 1. FIG.
Fig. 3 is a schematic side view for explaining the rotation mechanism of the rotating shaft shown in Fig. 1. Fig.
Fig. 4 is a front view showing a state in which the supply blade is omitted in the rotating shaft shown in Fig. 1. Fig.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, preferred embodiments of a sludge leveling device for a drum concentrator according to the present invention will be described in detail with reference to the drawings. It is to be understood that the terminology or words used herein are not to be construed in an ordinary sense or a dictionary, and that the inventor can properly define the concept of a term to describe its invention in the best possible way And should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

First, a drum concentrator provided with a sludge leveling device 100 according to the present invention will be described with reference to FIG. 1. For convenience, the left and right sides of the drum concentrator are referred to as rear and front, respectively, As shown in Fig.

The upper drum concentrator includes a frame 20 as a whole, as shown in FIG. The frame 20 is provided with a pair of support rods 14 located apart from each other in the left and right direction. The left and right ends of the rotation axis 12 of the cylindrical screen extending in the left- Respectively.

The cylindrical screen 10 slowly rotates in one direction (clockwise direction in FIG. 1) when the motor (not shown) is operated. At this time, the sludge S is placed on the surface of the rotating cylindrical screen 10, (The distance from 9 o'clock to 3 o'clock in the case of Fig. 1). On the surface of the cylindrical screen 10, filtrate holes (not shown) are provided. The filtrate, which the sludge S is faded during the movement of the sludge S, falls down through the filtrate holes . The dropped filtrate is collected by the filtrate receiver (30) installed in the frame (20) so as to be positioned below the cylindrical screen (10) and discharged to the outside.

The concentrated sludge separated from the filtrate, that is, the concentrated sludge S, is separated from the surface of the cylindrical screen 10 at a predetermined position (position at 3 o'clock in the case of Fig. 1) (Not shown) (for example, a filter cloth of a belt press to be used in a subsequent dehydration process) beneath the embers 40.

On the other hand, a washing nozzle 50 for spraying wash water to the cylindrical screen 10 to pierce the filtrate holes blocked by the sludge S is provided in the gastric drum thickener. The washing water dropped after being sprayed to the cylindrical screen 10 is collected by the filtrate receiver 30 and is discharged to the outside together with the filtrate.

The sludge leveling device 100 according to the present invention is provided in the drum concentrator as described above and is used for placing the sludge S on the surface of the cylindrical screen 10 at a predetermined position (position in the direction of 9 to 10 o'clock in FIG. 1) And includes a sludge chamber 110, a rotating shaft 130, and a plurality of supply blades 150, as shown in FIG.

The sludge chamber 110 includes a rear plate 114 and a sludge supply pipe 120 to which sludge S is supplied is coupled to a central portion of the rear plate 114. A left side plate 112a and a right side plate 112b are connected to left and right ends of the rear plate 114. A bottom plate 116 is connected to the lower ends of the rear plate 114 and the left and right side plates 112a and 112b. The front ends of the upper left and right side plates 112a and 112b are provided in the shape of an arc surface having the same curvature as the curvature of the cylindrical screen 10. [

This sludge chamber 110 is installed on a bracket 22 fixed to the frame 20 as shown in Fig. 1 with the front surface of the sludge chamber 110 opened in an open state. Then, the sludge chamber 110 is placed behind the cylindrical screen 10 At this time, the front ends of the upper left and right side plates 112a and 112b come into contact with the cylindrical screen 10 almost. Thus, the sludge S supplied from the sludge supply pipe 120 comes into contact with the surface of the cylindrical screen 10 while being accommodated in the sludge chamber 110.

The rotating shaft 130 is located inside the sludge chamber 110 so as to extend in the left and right direction and is located above the bottom plate 116 of the sludge chamber 110 Direction is shown). The left end of the rotating shaft 130 is rotatably coupled to the left plate 112a of the sludge chamber 110 and the right end is rotatably coupled to the right plate 112b of the sludge chamber 110. [

As shown in FIG. 3, a sprocket 130a is fixed to the right end of the rotary shaft 130 so as to be positioned outside the sludge chamber 110. Needless to say, the sprocket 130a can be fixed to the left end of the rotating shaft 130. [ The upper sprocket (130a) forms a spur gear with a driven sprocket (132) rotatably supported on the frame (20). The upper scoop 132 is connected to a drive sprocket 136 provided at the right end of the rotary shaft 12 of the cylindrical screen 10 via a chain 134. Accordingly, as shown in FIG. 1, when the cylindrical screen 10 rotates clockwise, the rotating shaft 130 rotates counterclockwise.

The gear ratio of the sprockets 130a, 132, 136 is set such that the rotating shaft 130 rotates faster than the cylindrical screen 10. [ For example, in FIG. 1, when the cylindrical screen 10 rotates by an angle of 30 minutes in the clockwise direction, the gear ratio is set such that the rotating shaft 130 rotates counterclockwise by one turn.

If the operating mechanism of the rotating shaft 130 is as described above, there is an advantage that the rotating shaft 130 can be rotated by a motor (not shown) for rotating the cylindrical screen 10.

Alternatively, the rotary shaft 130 may be rotated by a separate motor (not shown). In this case, in addition to the motor for rotating the cylindrical screen 10, a motor for rotating the rotating shaft 130 is separately required. However, since the rotation of the rotating shaft 130 is not interlocked with the rotation of the cylindrical screen 10 There is an advantage that the speed of the rotating shaft 130 can be freely adjusted.

The supply blades 150 are fixed to the outer surface of the rotating shaft 130 so as to extend from the left end to the right end of the rotating shaft 130, respectively. The supply blades 150 are arranged along the rotating direction of the rotating shaft 130 so as to be spaced apart from each other at regular intervals in a parallel posture. Figures 1 and 2 show an example in which four supply blades 150 are arranged at 90 degree intervals.

The protruding length of the supply blades 150, that is, the distance from the inner end fixed to the rotating shaft 130 to the outer end is set to be smaller than the distance between the surface of the rotating shaft 130 and the surface of the cylindrical screen 10 . Thus, the outer ends of the supply blades 140 are sequentially passed through a point spaced from the surface of the cylindrical screen 10 as shown in FIG. 1 when the rotating shaft 130 rotates.

When the sludge S is supplied from the sludge supply pipe 120, about half of the rotating shaft 130 is immersed in the sludge S as shown in FIG. When the rotating shaft 130 rotates in this state, the supply blades 150 sequentially push the sludge S in the sludge chamber 110 and put it on the surface of the cylindrical screen 10 which rotates relatively slowly .

Conventionally, the drum concentrator has been operated without the upper rotating shaft 130 and the supply blade 150, so that the sludge in the sludge chamber 110 is attracted by the rotating cylindrical screen 10 and mounted on the surface thereof. In this case, first, when the sludge S is accumulated in the sludge chamber 110, the sludge S is hardened near the left and right side plates 112a and 112b, and the sludge S in the vicinity of the left and right side plates 112a and 112b, A problem arises that the sludge S on the surface of the cylindrical screen 10 is not uniform in thickness.

However, since the supply blade 150 pushes the sludge S over the entire surface of the cylindrical screen 10 over the entire width of the sludge chamber 110, the sludge S in the vicinity of the left and right side plates 112a, Is placed on the surface of the cylindrical screen 10, and the sludge S is laid on the surface of the cylindrical screen 10 in an evenly spread state.

Since the sludge supply pipe 120 is provided at the center of the rear plate 114, the surface height of the sludge S contained in the sludge chamber 110 is relatively high at the center and gradually decreases toward the left and right side plates 112a and 112b There is a tendency. Particularly, when the viscosity of the sludge S is high, such tendency becomes more conspicuous. Therefore, in the present invention, a plurality of inclined blades 152 and 154 are provided to solve the problem of centralization of the sludge S. Hereinafter, the oblique blades 152 and 154 will be described in detail with reference to Figs. 2 and 4. Fig. 4, the illustration of the supply blade 150 is omitted so that all the inclined blades 152 and 154 can be seen clearly.

The upper bevel blades 152, 154 include left bevel blades 154 and right bevel blades 152.

Right inclined blades 152 are provided in the spacing spaces located on the right side with respect to the center of the rotating shaft 130. [ Here, the spacing spaces are spaces around the rotating shaft 130 separated by the supply blade 150, and refer to the spaces arranged in the rotating direction of the rotating shaft 130.

Each of the right-side inclined blades 152 is provided in the same shape and has an inner end fixed to the outer surface of the rotating shaft 130. Each of the right-side inclined blades 152 also has a head 152a and a tail 152b positioned in front of the head 152a when the rotational direction of the rotating shaft 130 is taken as a reference. The upper head 152a abuts the leading feed blade 150 and the upper tail 152b abuts the trailing feed blade 150 with the head positioned further to the right than the head 152a. Here, the line-following feeder blade 150 means the feeder blade 150 positioned adjacent to the front and rear sides, respectively, with reference to the rotating direction of the rotating shaft 130.

The arrangement of the right-side inclined blades 152 as described above can be set in various ways. For example, the upper right-side inclined blades 152 may be arranged at regular intervals from the center to the right as shown in FIG. 4, and may be arranged at intervals of 90 degrees in the clockwise direction when viewed from the center to the right. 4, four rightwardly inclined blades 152 are shown, but depending on the length of the rotating shaft 130 and the number of supply blades 152, the number of rightwardly inclined blades 152 may be less or more than four Of course.

Further, although not shown, the right-side inclined blades 152 may be provided at a plurality of points. For example, at the position where the right-side tilted blade 152 closest to the center is located in Fig. 4, another right-side tilted blade 152 may be provided at a position 180 degrees away from the right tilted blade 152, A right side slanting blade 152 may be further added so that a total of four slanting blades 152 are spaced 90 degrees apart. Such arrangement examples can be equally applied at the point where the remaining right-side inclined blades 152 are located.

The left side inclining blades 154 are provided in the spacing spaces located on the left side with respect to the center of the rotating shaft 130. [ Each of the left-side slanting blades 154 is provided in the same shape and has an inner end fixed to the outer surface of the rotating shaft 130. Each of the left side inclining blades 154 also has a head 154a and a tail 154b positioned in front of the rotating shaft 130 in reference to the rotating direction of the rotating shaft 130. [ The upper head 154a abuts the leading feed blade 150 and the upper tail 154b abuts the trailing feed blade 150 with the head positioned further to the left than the head 152a. The left side incline blades 154 are arranged to be symmetrical with the right side incline blades 152.

The right side sloping blades 152 push the sludge S pushed toward the cylindrical screen 10 toward the right by the supply blade 130 and the left side sloping blades 154 push the sludge S toward the supply blade 130 130 push the sludge S pushed toward the cylindrical screen 10 to the left at the same time and in the same spacing space. Therefore, the sludge S concentrated at the center in the sludge chamber 110 spreads to the left and right by the inclined blades 152 simultaneously with the rotation of the rotating shaft 130 by the supply blade 150, The sludge S is not concentrated at the center but spreads to the left and right so as to be laid on the surface of the cylindrical screen 10. [

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: cylindrical screen 12: rotating shaft
20: frame 30: filtrate receiver
40: Stomach 50: Wash nozzle
100: Sludge equalizer for drum concentrator
110: sludge chamber 112a, 112b: left and right side plates
114: back plate 116: bottom plate
120: sludge supply pipe 130: rotary shaft
130a, 132, 136: sprocket 134: chain
150: Feed blade 152: Right-side inclined blade
154: left side inclination blade 152a, 154a:
152b, 154b: tail S: sludge

Claims (5)

And a cylindrical screen disposed on the surface of the sludge for separating the filtrate from the sludge while rotating around a rotation axis extending in the left and right direction,
A sludge chamber provided to be able to receive sludge from the outside and installed adjacently to the cylindrical screen, the sludge chamber having an open front side to allow the supplied sludge to contact the surface of the cylindrical screen;
A rotating shaft having left and right ends rotatably coupled to the left and right sides of the sludge chamber, the rotating shaft being operative to rotate in a direction opposite to the cylindrical screen; And
And is fixed to the outer surface of the rotating shaft so as to be arranged along the rotating direction of the rotating shaft while being in a posture extending from the left end to the right end of the rotating shaft and passes through a point spaced from the surface of the cylindrical screen when the rotating shaft rotates A plurality of supply blades for pushing sludge in the sludge chamber and placing the sludge on the surface of the cylindrical screen,
The slanting blades are fixed to the spacing spaces divided by the supply blades and arranged in the rotating direction of the rotating shaft. In each of the spacing spaces on the left side with respect to the center of the rotating shaft, a slope And at least one right-side inclined blade having an inclination for pushing the sludge to the right is fixed to each of the spaced-apart spaces located on the right side of the drum-concentrator. delete The method according to claim 1,
Wherein the left and right tilting blades have a head and a tail respectively abutting a line-following supply blade which is to be carried out after rotation of the rotating shaft, the tail being located farther from the center of the rotating shaft than the head. The method according to claim 1 or 3,
Wherein the rotating shaft is configured to rotate faster than the cylindrical screen. 5. The method of claim 4,
The sprocket provided at one end of the rotary shaft forms a driven sprocket and a spur gear which are shrouded outside the sludge chamber. The driven sprocket is connected to a driving scoop provided at one end of the rotary shaft of the cylindrical screen through a chain, Sludge supply system.

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