KR101087672B1 - Moving-belt type apparatus for preventing adherence sludge to settling pond - Google Patents

Abstract

PURPOSE: A moving belt type sludge eliminating apparatus is provided to improve the space using efficiency of a precipitating bath by simplifying the internal structure of the precipitating bath. CONSTITUTION: A moving belt type sludge eliminating apparatus includes moving plates(400, 500), a driving part(150), and a dividing wall(200). A plurality of moving plates forms layers in a precipitating bath(100). The moving plates caterpillar rotate based on rotary shafts(420, 430) which are arranged at both end parts of the moving plates. The dividing wall divides the flowing path of water through the moving plates and guides the water to different discharging parts. Sludge accumulated on the moving plates are moved along the moving plates and are discharged through a hopper(300).

Description

Moving-belt type apparatus for preventing adherence sludge to settling pond}

The present invention relates to a sedimentation basin in a water and sewage treatment plant, and more particularly to a moving belt type sludge eliminator for removing and removing sludge accumulated in the sedimentation basin in a hopper more efficiently.

1 is a schematic diagram showing the configuration of a sludge removal apparatus of a conventional rechargeable battery.

In the sewage treatment process, sludge accumulates inside the sedimentation basin. Such sludge must be discharged periodically so that effective sewage treatment can be continuously performed.

To this end, conventionally, various sludge removal apparatuses, such as an underwater bogie type sludge remover (Fig. 1 (a)), a link chain sludge remover (Fig. 1 (b)), or a moving bridge type sludge remover (Fig. 1 (c)), are used. I'm proposing.

However, such a conventional sludge removal apparatus was difficult to maintain due to the sludge is not completely removed or the structure is complicated in operation.

In more detail, in the case of the subsea-type sludge remover (FIG. 1 (a)), the bogie 3 moved by the driving motor 1 removes the sludge at the bottom of the hopper in the direction of the hopper A. The movement control of the trolley | bogie 3 by (2) has a limit, and there exists a problem that the part which the trolley | bogie 3 which has a fixed size or more does not reach | occur | produce.

In the case of the link chain sludge remover (Fig. 1 (b)), when the drive motor 1 'rotates the chain 2', the scraper 3 'provided on the chain moves the bottom sludge to the hopper A. Will be removed. However, in this case, the length of the chain 2 'is long, the maintenance is inferior, and there is a disadvantage that it is difficult to use in a multilayered precipitation structure, which is a technique recently used.

Finally, in the case of a mobile bridge type sludge remover (FIG. 1 (c)), the trastle (1 '') is moved along the rail (2 '') installed in the upper part of the settling basin (1 '') The scraper 3 '' connected to the sludge guides the sludge in the hopper direction. However, this method is also difficult to use in the multi-layer sedimentation structure, which is a recently used technique, and since only the scraper 3 '' is moved in the water, it is difficult to precisely adjust the scraper 3 '', thereby limiting sludge removal.

In addition, recently, in order to increase sedimentation efficiency by installing a plurality of sedimentation plates inside the sedimentation basin, it is difficult to remove all the sludge accumulated in each sedimentation plate when the sedimentation plate is composed of a plurality of layers. There is a problem.

The present invention is to solve the problems of the prior art as described above, the present invention is to effectively remove the sludge accumulated in each of the sedimentation plate composed of a plurality of layers inside the sedimentation basin.

Another object of the present invention is to make it possible to perform both functions without dualizing the device for the smooth removal of sludge in the sedimentation basin and the sludge removal apparatus.

According to a feature of the present invention for achieving the object as described above, the present invention is a moving belt type sludge remover for the smooth removal of the sludge in the sedimentation basin, consisting of a plurality of layers to be formed inside the sedimentation basin at both ends A moving plate configured to be rotatable in a caterpillar structure based on the rotated axis, a driving unit connected to at least one of the two rotating shafts of the moving plate to provide a rotational force, and one end of the moving plate It is installed to cross the inside of the sedimentation basin at a position to include a partition wall for partitioning the movement path of the water to be passed through each of the plurality of moving plate to be discharged to different discharge parts, the rotating moving The sludge deposited on the plate accumulates in the moving plate It moves along and is discharged to fall into a hopper which is formed at a position corresponding to one end of the moving plate.

The moving plate is rotated such that its upper surface moves in a direction opposite to the flow direction of the water to be treated.

At least one of the two rotating shafts is composed of a driving roller and the driving roller is connected by the drive unit and the chain is rotated, the drive unit is provided with a reducer can adjust the rotational speed of the moving plate.

One end facing the hopper of the moving plate positioned relatively upward among the moving plates composed of the plurality of layers is shorter than one end facing the hopper of the moving plate positioned relatively downward.

The moving plate is composed of follicles.

A plurality of deflection prevention rods are installed along the rotation path of the moving plate to prevent the moving plate from sagging.

One end of the moving plate facing the hopper is provided with a scraper to scrape the sludge accumulated on the outer surface of the moving plate during the rotation of the moving plate.

At least some of the plurality of moving plates are installed to be inclined downward toward the hopper.

In the moving belt type sludge remover according to the present invention as described above, the following effects can be expected.

In the present invention, since the moving plate installed inside the sedimentation basin rotates in an endless track manner, the sludge accumulated on the upper surface of the sedimentation basin continuously discharges the sludge, and the apparatus for smooth removal of the sludge in the sedimentation basin is a sedimentation plate. Since both functions can be performed by the moving plate without dualizing with the sludge removal device, the structure inside the sedimentation basin is simplified, and the space utilization rate of the sedimentation basin is improved because the installation space is not required separately.

In addition, in the present invention, a plurality of moving plates are provided in layers in the sedimentation basin, and the treated water passing through them is discharged through different discharge ports by the partition walls, so that the sedimentation efficiency is improved, and each sedimentation plate (moving plate) is provided. As the sludge accumulated during the rotation is continuously discharged, sludge accumulation can be prevented in the same manner.

In addition, since the present invention is made by additionally installing a moving plate without modifying the existing sedimentation basin, there is also an effect that can be utilized as it is.

1 is a schematic view showing the configuration of a sludge removing apparatus of a conventional rechargeable battery.
Figure 2 is an internal configuration showing the configuration of the sedimentation basin inside the moving belt type sludge remover according to the present invention.
Figure 3 is a perspective view showing the configuration of a moving plate constituting an embodiment of the present invention.
Figure 4 is a perspective view showing the configuration of the moving plate and the scraper provided therein constituting an embodiment of the present invention.
Figure 5 is an internal configuration showing the configuration of the sedimentation basin is applied to another embodiment of the moving belt type sludge remover according to the present invention.
Figure 6 is an internal configuration showing the configuration of the sedimentation basin applied to another embodiment of the moving belt type sludge remover according to the present invention.

Hereinafter, with reference to the accompanying drawings a specific embodiment of the moving belt type sludge remover according to the present invention as described above will be described in detail.

Figure 2 shows the internal configuration of the sedimentation basin is applied to the moving belt type sludge remover according to the present invention.

According to this, the moving belt type sludge removal apparatus includes a moving plate 400 and 500, a driving unit 150, and a partition wall 200, which will be described below in detail.

First, referring to the sedimentation basin 100, the inlet gate 110 is provided in the sedimentation basin 100. The inflow gate 110 is a portion for selectively introducing the water to be treated (water to be purified), a plurality of inflow paths 115 are formed in the inflow gate 110, through which the treated water is settled (100) Flows into the interior.

The settling basin 100, the driving unit 150 is installed. The driving unit 150 is for transmitting the rotational force to the moving plate (400,500), is installed on the upper portion of the settling basin (100). In this embodiment, the driving unit 150 is composed of a motor, the driving unit 150 generates a rotational force by fossil fuel such as electricity or gasoline.

At this time, although not shown, the driving unit 150 may include a deceleration means. The deceleration means is to adjust the rotational force generated by the drive unit 150, the excessive rotational force is not transmitted to the moving plate (400, 500) by the drive unit 150, it is possible to maintain a suitable rotational speed. This is because the sludge included in the water to be treated accumulates in the moving plates 400 and 500 over a long time, so that the rotation speed of the moving plates 400 and 500 is preferably kept sufficiently slow. In this embodiment, the moving speed of the moving plates 400 and 500 by the speed reducer is 0.6 m / sec or less.

Of course, the deceleration means is configured to be adjustable by the user, as a result can also adjust the rotational speed of the moving plate (400,500). Reference numeral 151 denotes a belt or a chain for transmitting rotational force to the rotation shafts 420 and 430.

The connection belt 160 is connected to the driving unit 150. The connecting belt 160 is for transmitting the rotational force of the driving unit 150 to the moving plates 400 and 500 and extends in the vertical direction. The connecting belt 160 may be in a chain form.

For reference, in the present embodiment, two driving units 150 and two connecting belts 160 are provided because two moving plates 400 and 500 are provided as described below.

On the other hand, one side of the sedimentation basin 100 is provided with outflow traps (170, 180), the outflow traps (170, 180) correspond to a kind of discharge passage that the supernatant is finally discharged.

In this case, the outlet traps 170 and 180 include a first trap 170 and a second trap 180. The first trap 170 and the second trap 180 is configured to be separated from each other, through which the superior number of the water to be treated passing through the first space (A) and the second space (B) to be described below Are discharged separately.

That is, after sludge is deposited while the water to be treated passes through the first space A, which is a space on the first moving plate 400, the supernatant is discharged to the first trap 170. Likewise, the sludge precipitated while passing through the second space B, which is a space on the second moving plate 500, is discharged through the second trap 180.

In this case, the first trap 170 and the second trap 180 is partitioned by the partition wall 200. One end of the partition wall 200 is positioned between the first and second traps 170 and 180, and the other end thereof extends to one end of the first moving plate 400 to be described below. Accordingly, the partition wall 200 blocks the treated water flowing into the first space A so as not to be discharged to the second trap 180.

Next, the moving plates 400 and 500 will be described. First, the moving plates 400 and 500 may include a first moving plate 400 and a second moving plate 500. The moving plates 400 and 500 simultaneously serve as a precipitation plate in which sludge is accumulated and simultaneously discharge the sludge into the hopper 300.

As the moving plates 400 and 500 are composed of the first moving plate 400 and the second moving plate 500, there are two precipitation plates on which sludge may accumulate. Accordingly, the total sedimentation area inside the sedimentation basin 100 becomes about two, and the sedimentation efficiency can be improved.

Since the first moving plate 400 and the second moving plate 500 have a similar structure, hereinafter, the first moving plate 400 will be described based on the first moving plate 400.

More specifically, the first moving plate 400 is provided along the inner space of the sedimentation basin 100, and the sludge contained in the water to be treated is dropped by gravity. In addition, since the first moving plate 400 is continuously rotated in a caterpillar manner, the sludge may be moved and discharged in the process.

At this time, the first moving plate 400 is configured to be rotatable in a caterpillar structure around the rotation shafts 420 and 430 provided at both ends. That is, the first moving plate 400 is to rotate the entire outer surface continuously, accordingly, the outer surface of the first moving plate 400 is directed upward and after a predetermined time (after passing the rotating shaft (420,430)) ) Repeat to face down.

Accordingly, when the outer surface of the first moving plate 400 faces downward, the sludge accumulated on the outer surface of the first moving plate 400 falls by gravity.

The first moving plate 400 is rotated such that its upper surface directed upward moves in a direction opposite to the flow direction of the water to be treated. That is, referring to FIG. 2, since the water to be treated flows to the right (arrow ① direction), the first moving plate 400 is rotated counterclockwise. This is to allow the sludge to accumulate more efficiently on the upper surface of the first moving plate 400.

Looking at the structure of the first moving plate 400, the first moving plate 400 is composed of two rotating shafts (420,430) and the plate body (410). The two rotation shafts 420 and 430 are composed of a driving shaft 420 connected to the driving unit 150 again and a driven shaft 430 interlocked with the rotation of the driving shaft 420.

As shown in FIG. 3, the driving unit 425 is provided to protrude from the driving shaft 420, and the operating unit 425 is connected to the connection belt 160 to be rotated. In this embodiment, gears corresponding to each other are formed in the operation unit 425 and the connection belt 160, and are rotated without being slipped, but are not necessarily limited thereto. For example, the connecting belt 160 may be configured in a chain form.

On the other hand, as shown in Figure 3 is the sag prevention rod 470 is provided in the middle of the plate body 410. The sag prevention bar 470 is intermittently provided along the longitudinal direction of the plate body 410 in order to prevent the plate body 410 from sagging downward by gravity.

In addition, a rotation guide 440 is further provided between the two rotation shafts 420 and 430 to induce smooth rotation of the plate body 410.

One side of the first moving plate 400 is provided with a scraper 450. The scraper 450 is to scrape the sludge accumulated on the outer surface of the first moving plate 400 during the rotation of the first moving plate 400. That is, the scraper 450 is sludge accumulated on the upper surface of the first moving plate 400 is stored in the plate body 410 is not dropped by gravity even if the plate body 410 is rotated to face downward It is to prevent that.

More precisely, the scraper 450 is installed to be located on either side of the drive shaft 420 or the driven shaft 430, and the moment when the outer surface of the plate body 410 is changed from the upper surface to the lower surface or the upper surface from the lower surface to the upper surface. The sludge on the outer surface of the plate body 410 is scratched.

At this time, as shown in Figure 4, the scraper 450 may be installed to be connected to the drive shaft 420. That is, the scraper 450 is installed on the drive shaft 420 by the link 452, but is not necessarily limited thereto, and may be directly installed on the inner wall of the settler 100.

The front end 451 of the scraper 450 is preferably formed to have a smaller thickness and is in close contact with the outer surface of the plate body 410.

On the other hand, the plate body 410 may be composed of a filter cloth (filter cloth). That is, the plate body 410 itself is composed of follicles. This may allow the follicle to act as a sedimentation plate and to remove sludge. Of course, the plate body 410 may be made of a material of a general rotating belt.

The first moving plate 400 is formed to be relatively shorter than the second moving plate 500. In other words, one end of the first moving plate 400 facing the hopper 300 is formed to be shorter than the second moving plate 500.

This is to allow the second moving plate 500 to be discharged to the hopper 300 while the sludge falling from the first moving plate 400 is seated on the upper surface of the second moving plate 500.

Meanwhile, FIGS. 5 and 6 show other embodiments of the sedimentation basin 100 sludge accumulation prevention apparatus according to the present invention.

As shown in the drawing, the moving plates 400, 500, and 600 may be configured as three. Accordingly, the settling efficiency of the settler 100 may be further improved. In this case, there are a total of three inferior traps 170, 180, and 190, and two partition walls 200 for partitioning them are also configured.

In addition, as shown in FIG. 6, some of the moving plates 400, 500, and 600 may be installed to be inclined downward toward the hopper 300. This is to allow the sludge on the upper surfaces of the moving plates 400 and 500 to fall more easily.

Hereinafter, the operation of the moving belt type sludge remover according to the present invention will be described.

Looking at the process of sedimentation and sludge sedimentation basin 100 according to the present invention, the treated water introduced into the sedimentation basin 100 through the inlet gate 110 first flows along the interior of the sedimentation basin 100.

At this time, the inside of the sedimentation basin 100 is divided into the first space (A) and the second space (B) on the basis of the first moving plate 400, so that some water to be treated is the first space (A), Flows along the second space (B).

Sludge generated from the water to be treated flowing along the first space (A) is settled on the upper surface of the first moving plate 400, sludge generated from the water to be treated flowing along the second space (B) It is deposited on the upper surface of the second moving plate 500.

And, the precipitated supernatant is discharged to the outside through the first trap 170 and the second trap 180, respectively. At this time, since the partition wall 200 is installed between the first trap 170 and the second trap 180, the upper water of the treated water flowing along the first space (A) is the second trap ( Discharge through 180, or vice versa.

On the other hand, the sludge deposited on the first moving plate 400 and the second moving plate 500 is moved in accordance with the rotation of the first moving plate 400 and the second moving plate 500 and finally the hopper 300 Will fall).

More specifically, since both of the first moving plate 400 and the second moving plate 500 have an acyclic orbital structure, the outer surface of the plate body 410 facing upward is also directed downward after a predetermined time. Accordingly, the sludge deposited on the outer surface of the plate body 410 is naturally discharged by gravity.

In this case, a scraper 450 may be installed on the first moving plate 400 and the second moving plate 500 to allow the precipitated sludge to be more efficiently scraped out from the outer surface of the plate body 410.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

100: sedimentation basin 110: inflow gate
150: driving unit 200: partition wall
300: hopper 400: first moving plate
500: second moving plate

Claims (8)

Moving belt type sludge remover for smooth removal of sludge in sedimentation basin,
A moving plate composed of a plurality of layers to form a layer in the sedimentation basin and rotatably configured in a caterpillar structure based on a rotation axis provided at both ends;
A driving unit connected to at least one of the two rotating shafts of the moving plate to provide a rotating force;
Including a partition wall installed to cross the inside of the sedimentation basin at a position corresponding to one end of the moving plate to partition the moving path of the water to pass through each of the plurality of moving plates to guide the discharge to different discharge parts Consist of,
The sludge deposited and accumulated on the rotating plate is discharged by dropping into a hopper formed at a position corresponding to one end of the moving plate while moving along the moving plate.
The moving plate is rotated so that its upper surface moves in a direction opposite to the flow direction of the water to be treated,
At least one of the two rotating shafts are composed of a driving roller and the driving roller is connected by the drive unit and the chain is rotated, the drive unit is provided with a reducer is adjustable the rotational speed of the moving plate,
Moving belt type sludge, characterized in that the one end toward the hopper of the moving plate located relatively upward among the moving plate composed of the plurality of layers is formed shorter than the one toward the hopper of the moving plate located relatively downward Eliminator.
delete delete delete The moving belt type sludge remover of claim 1, wherein the moving plate is made of follicles.
The moving belt type sludge remover of claim 5, wherein a plurality of deflection prevention rods are installed along a rotation path of the moving plate to prevent the moving plate from sagging.
According to any one of claims 1, 5 or 6, one end of the moving plate facing the hopper is provided with a scraper, scraping the sludge accumulated on the outer surface of the moving plate during the rotation of the moving plate Moving belt type sludge remover, characterized by.
The moving belt type sludge remover of claim 7, wherein at least some of the plurality of moving plates are installed to be inclined downward toward the hopper.

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