KR100713774B1 - Impeller for reservoir water - Google Patents

Abstract

The present invention relates to an impeller for preventing sludge settling in a storage tank, and an impeller (disk plate) formed to prevent sedimentation of sludge by rotating in a storage tank (underwater) is combined with a separate rotary shaft, A bearing is provided on the lower rotation part of the rotary shaft to support and guide the rotary drive, and a separate member is provided on the rotary shaft so that floating matters such as dirt and debris generated from the sludge introduced into the bearing can not be settled. 2 impeller is installed so that the rotating part bearing in the storage tank is smoothly driven so as to smoothly rotate the rotating shaft while preventing the overload of the motor as the driving unit and furthermore, The sludge settling prevention of the storage tank It relates to the impeller.

The upper end of the body is rotatably driven by the driving device 110 and the lower end of the body is supported by the rotary part 120 including the bearing 121 and is rotated to form a rotation axis 100. In the sludge storage tank, and; A first disc plate 210 coupled to one side of the rotating shaft 100 and coupled to the rotating shaft 100 so as to prevent sedimentation of the introduced sludge from the bottom of the rotating disc 100, A first impeller 200 having a plurality of first blades 220 arranged at equal intervals along a circumferential direction on a lower outer circumferential surface of the first disc plate 210 and vertically coupled to the first disc plate 210 to urge a vortex, Wow; A second disk plate 310 formed on the upper end of the rotating portion 120 of the rotating shaft and vertically coupled to the rotating shaft 100 to prevent the deposited sludge from flowing into the bearing, A second impeller 300 having a plurality of second blades 320 formed on the lower outer circumferential surface of the second disk plate 310 in a radial direction at regular intervals along the circumferential direction, end; .

Therefore, according to the present invention, the second impeller is additionally provided at a close distance of the rotary part (bearing side) so that the bearing of the rotary shaft is not damaged or contaminated by the sludge sediment, thereby preventing contamination of the bearing, Thereby preventing overloading of the drive unit (motor), and moreover, it is possible to more smoothly form the liquid environment of the storage tank flowing into the transfer pump.

Reservoir, sludge, sediment, impeller, rotating shaft, bearing, disk plate, blade

Description

[0001] Impeller for reservoir water [0002]

FIG. 1 is a flowchart of a general surplus sludge treatment process,

FIG. 2 is a side view showing the interior of a storage tank with an impeller (disk plate and blade) according to the present invention,

3 is a bottom view of the impeller according to the present invention.

Description of the Related Art [0002]

100 ... rotation shaft 110 ... drive device

120 ... rotation part 121 ... bearing

200 ... first impeller 210 ... first disc plate

220 ... 1st blade

300 ... second impeller 310 ... second disc plate

320 ... 2nd blade

The present invention relates to an impeller for preventing sludge settling in a storage tank, and an impeller (disk plate) formed to prevent sedimentation of sludge by rotating in a storage tank (underwater) is combined with a separate rotary shaft, A bearing is provided on the lower rotation part of the rotary shaft to support and guide the rotary drive, and a separate member is provided on the rotary shaft so that floating matters such as dirt and debris generated from the sludge introduced into the bearing can not be settled. 2 impeller is installed so that the rotating part bearing in the storage tank is smoothly driven so as to smoothly rotate the rotating shaft while preventing the overload of the motor as the driving unit and furthermore, The sludge settling prevention of the storage tank It relates to the impeller.

Generally, sewage or waste water contains a large amount of suspended solids. These solids are finally separated into filtrate and sludge cake by several stages of purification, concentration, coagulation and dehydration systems.

The sludge obtained by separating the supernatant from a sedimentation tank such as a sewage treatment plant or a wastewater treatment plant is usually low in concentration (water content 99.3 to 99.5 wt%), and the low concentration sludge is buried, incinerated or recycled.

Meanwhile, in the conventional sludge treatment process, as shown in FIG. 1, the raw water (o, wastewater, sewage, etc.) flows into the first settling basin and is collected.

Thus, the low concentration sludge flowing from the final sedimentation tank through the excess sludge drawing pump is firstly introduced into the sludge storage tank as the auxiliary tank concept (sludge concentration 0.6 to 1.0%).

Then, a separate sludge conveying pump, which is formed at one side of the primary sludge storage tank in the direction of the proceeding direction pipe, transfers the low concentration sludge to the centrifugal concentrator.

At this time, the centrifugal concentrator separates the low-concentration sludge by solid-liquid separation and separates into a filtrate and concentrated sludge (sludge concentration 2.5-3.5%). At this time, the concentrated sludge is stored in a separate secondary sludge storage tank.

Thereafter, another concentrated sludge conveying pump is installed from the secondary sludge storage tank to one side of the proceeding direction pipe to convey the high concentration sludge to the centrifugal dehydrator side.

At this time, the centrifugal dehydrator is formed so as to maximize dewatering of the concentrated sludge introduced once more by solid-liquid separation by rotary centrifugal force, thereby effectively separating the filtrate and the cake.

In the sludge storage tank, the low-concentration sludge introduced from the final sedimentation tank is floated and collected. At this time, the low-concentration sludge liquid contains a large amount of solid matter (suspended matter).

This solid matter, that is, the sludge is continuously collected in proportion to time, it is precipitated on the bottom surface of the storage tank as well as decayed to cause the generation of odor and noxious gas, and when the sludge is accumulated on the bottom surface too much, Paralyzed and adversely affect the smooth sludge treatment process. In addition, due to the continuous sedimentation of the sludge, a pump for inducing continuous operation in the subsequent process is blocked, which shortens the replacement period of other devices.

In recent years, a sludge vortex impeller (propeller, etc.) rotated from a separate driving motor is installed on the vertical line of the middle of the storage tank to induce sedimentation of the sludge in the storage tank.

However, the conventional impeller has a shape similar to a propeller of an airplane, which requires a driving force not enough to rotate the motor in the water, resulting in a large-sized driving motor.

A rotating shaft extending from a driving shaft for rotating the impeller is formed with a separate follower including a bearing at its lower portion, that is, a rotating portion. The rotating portion has a difference in height (height difference) from the impeller for promoting eddy flow, (4 ~ 5m), so that the sedimentation of the sludge continues, and in particular, dirt (solid matter) etc. is settled in the bearing, which interferes with smooth rotation, thereby causing breakage of the apparatus including the rotating shaft and the driving motor.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide an impeller (disk plate) which rotates in a storage tank (water) and prevents precipitation of sludge, The bearing is provided at a lower end side rotating portion of the rotating shaft so as to support and guide the rotating drive. At the upper end close position of the bearing, a separate second By installing the impeller, the rotating part bearing in the storage tank is formed to be smoothly driven to smoothly rotate the rotating shaft, while preventing the overload of the motor as the driving device and further improving the concentration of the stored liquid flowing into the transfer pump. A sludge settling prevention impeller It is an object to provide.

To achieve the above object, the present invention provides a sludge storage tank, wherein an upper end of the body is rotatably driven by a driving device (110) and a lower end is supported by a rotating part (120) including a bearing (121) A rotary shaft (100); A first disc plate 210 coupled to one side of the rotating shaft 100 and coupled to the rotating shaft 100 so as to prevent sedimentation of the introduced sludge from the bottom of the rotating disc 100, A first impeller 200 having a plurality of first blades 220 arranged at equal intervals along a circumferential direction on a lower outer circumferential surface of the first disc plate 210 and vertically coupled to the first disc plate 210 to urge a vortex, end; .

The second disk plate 310 is coupled to the rotation shaft 100 so that the deposited sludge does not flow into the bearing, and the second disk plate 310 A second impeller 300 having a plurality of second blades 320 formed on the lower outer circumferential surface in the radial direction along the circumferential direction at regular intervals and being vertically coupled to the second disk plate 310 to form a vortex, end; .

The second impeller 300 is formed such that the diameter of the disk plate 310 is equal to the outer diameter of the rotary part 120 including the bearing 121 while the lower end surface of the blade 320 is connected to the bearing It is preferable to be formed so as to be disposed within a distance of 10 to 50 cm from the upper end side of the upper surface of the base plate 121.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the accompanying drawings.

2 to 3, the present invention is formed in a sludge storage tank so that a low-concentration sludge in the form of a solid is not precipitated by a vortex. This is because the rotary shaft 100 including the driving device 110 (motor and speed reducer) A first impeller 200 formed on one axial side of the rotary shaft 100 and a second impeller 200 formed on the axial lower end of the rotary shaft 100.

The upper end of the rotating shaft 100 is rotatably driven by the driving unit 110 and the lower end of the rotating shaft 100 is supported by the rotating unit 120 including the bearing 121 and rotated.

The rotary shaft 100 is preferably made of a metal material which is not corroded or contaminated by the stored low concentration sludge. In particular, the rotary shaft 100 is formed to be perpendicular to the center bottom of the storage tank, and has a length corresponding to the depth of the storage tank.

In addition, the driving device 110 is formed of a general motor and a speed reducer, and the capacity and size of the driving device 110 are preferably formed to correspond to the size of the storage tank.

At the lower end of the rotary shaft 100, that is, the bottom surface of the storage tank, a rotary part 120 is formed to support the rotary shaft to support the rotary shaft. The rotary part 102 has a groove formed at the center of the body The bearing 121 is received in the bearing 121 in correspondence with the lower end of the rotary shaft 100. At this time, the bearing 121 is preferably a conventional underwater bearing.

The first impeller 200 includes a disk-shaped first disk plate 210 coupled to one side of a shaft of the rotating shaft 100 and vertically coupled to the rotating shaft 100 so as to prevent sedimentation of the introduced sludge, A plurality of first blades 220 arranged radially and equidistantly in a circumferential direction on the lower outer peripheral surface of the first disk plate 210 and vertically coupled to the first disk plate 210 to urge a vortex, Respectively.

In this case, the first disk plate 210 is provided with a separate bushing having a through hole at the center of the body so as to be perpendicular to the rotation axis. The bushing and the rotation shaft penetrate from the outer peripheral side of the bushing, Which is connected to a separate fastener.

The disc-shaped first disc plate 210 is less in rotational resistance than a conventional propeller (impeller), thereby preventing an overload of the drive unit 110, and in particular, realizes a low capacity of a motor and a speed reducer.

A plurality of first blades 220 are fixedly coupled to the bottom surface of the first disk plate 210 by welding or bolting. The first blades 220 are coupled to the first disk plate 210 Are vertically coupled to the bottom surface, and are formed to be equally spaced along the circumferential direction.

At this time, it is preferable that the first blade 220 is formed such that the lower end of the first blade 220 is tilted rearward by a predetermined angle with respect to the rotation direction, so that the load according to the rotational force is minimized.

That is, as the vortex phenomenon is promoted, the underwater sludge is rotationally driven so as to be perpendicularly coupled to the bottom surface of the first disk plate 210 so that excessive overload is not applied to the rotary shaft 100 including the drive motor 110 But it is preferable to be inclined such that it forms an oblique line (inclined angle - for example, 15 to 45 degrees).

At this time, the first blade 220 preferably has a size of about 1/5 to 1/10 with respect to the disk-shaped first disk plate 210, and the number of the first blades 220 is preferably 4 to 50 . This is in order to cope with the catchment area of the storage tank and to make it correspond to the manufacturing reference value.
That is, the first blades 220 are coupled to the bottom surface of the first disk plate 210, and one entire area (rectangular area) of the first blades 220 is formed in a circular plate shape of the first disk plate 210 It is preferable to have a small size of 1/5 to 1/10 with respect to the total area (circular width).

In addition, the first impeller 200 is installed on the axis of rotation axis within the storage tank, and the installed position thereof is connected to the center of the storage tank, that is, the center point of the rotation axis. More preferably, the height of the collected sludge and vortex efficiency It is preferable that the installation position is variable.

On the other hand, the second impeller 300 has the same size (size) as the first impeller, and the sludge does not flow into the bearing A second disk plate 310 coupled to the second disk plate 310 so as to be vertically coupled to the rotation axis 100 and a second disk plate 310 disposed radially and equidistantly along a circumferential direction on a lower end peripheral surface of the second disk plate 310, And a plurality of second blades 320 are provided so as to be vertically coupled to the vanes 310 to induce a vortex.

In this case, the second disk plate 310 is provided with a separate bushing having a through hole at the center of the body so as to be perpendicular to the rotation axis. The bushing and the rotation shaft penetrate from the outer peripheral surface side of the bushing, Which is connected to a separate fastener.

The disk-shaped second disk plate 310 is less in rotational resistance than a conventional propeller (impeller), thereby preventing an overload of the drive unit 110, and realizes a particularly low capacity of a motor and a speed reducer.

A plurality of second blades 320 are fixedly coupled to the bottom surface of the second disk plate 310 by welding or bolting. The second blades 320 are coupled to the second disk plate 310 Are vertically coupled to the bottom surface, and are formed to be equally spaced along the circumferential direction.

At this time, it is preferable that the second blade 320 is formed such that the lower end of the second blade 320 is inclined rearward by a predetermined angle with respect to the rotation direction, so that the load according to the rotational force is minimized.

That is, when the underwater sludge is driven to rotate in the vortexing direction, the sludge is coupled to the bottom surface of the second disk plate 310 by a vertical line so that excessive overload is not applied to the rotating shaft 100 including the driving motor 110 But it is preferable to be inclined such that it forms an oblique line (inclined angle - for example, 15 to 45 degrees).

At this time, the second blade 320 is preferably about 1/5 to 1/10 of the disk-shaped second disk plate 310, and more preferably, the number of the second blades 320 is 4 to 50 . This is in order to cope with the catchment area of the storage tank and to make it correspond to the manufacturing reference value.
That is, the second blades 320 are respectively coupled to the bottom surface of the second disk plate 310, and one entire area (square width) of the second blades 320 is formed in a circular plate shape of the second disk plate 310 It is preferable to have a small size of 1/5 to 1/10 with respect to the total area (circular width).

The second impeller 300 having such a small size prevents the sludge that can be settled on the upper surface of the rotary part 120, whose main purpose is the lower end of the rotary shaft 100, from flowing into the bearing 121.

The second impeller 300 is formed such that the diameter of the disk plate 310 is equal to the outer diameter of the rotation part 120 including the bearing 121 while the lower end surface of the blade 320 is supported by the bearing 121) at an interval of 10 to 50 cm from the upper end side.

That is, the rotation unit 120 corresponding to the driven shaft from the drive unit 110 does not improve the precipitation prevention from the first impeller 200 formed on the rotating shaft. This is because the second impeller 300 of the present invention Thereby preventing sludge from settling or flowing into the bearing.

As described above, according to the present invention, the second impeller is additionally provided at a close distance of the rotary part (bearing side) so that the bearing of the rotary shaft is not damaged or contaminated by the sludge precipitate, Thereby preventing overloading of the drive unit (motor), and moreover, forming a liquid environment of the storage tank to be introduced into the transfer pump more smoothly.

Claims (3)

In the sludge storage tank, The upper end of the body is rotationally driven by the driving device 110 and the lower end is supported by the rotary part 120 including the bearing 121 and is configured to rotate; A first disc plate 210 coupled to one side of the rotating shaft 100 and coupled to the rotating shaft 100 so as to prevent sedimentation of the introduced sludge from the bottom of the rotating disc 100, A first impeller 200 having a plurality of first blades 220 arranged at equal intervals along a circumferential direction on a lower outer circumferential surface of the first disc plate 210 and vertically coupled to the first disc plate 210 to urge a vortex, end; Wherein the impeller is disposed on the outer surface of the impeller. [3] The apparatus according to claim 1, wherein the rotating shaft (120) A second disk plate 310 having a disk shape and vertically coupled to the rotating shaft 100 so as to prevent the sedimented sludge from flowing into the bearing side and a second disk plate 310 having a radial shape along the circumferential direction on the outer peripheral surface of the lower end of the second disk plate 310 A second impeller (300) having a plurality of second blades (320) arranged to be spaced apart from each other and vertically coupled to the second disc plate (310) to urge a vortex; Wherein the impeller is disposed on the outer surface of the impeller. 3. The apparatus of claim 1, wherein the second impeller (300) The lower end surface of the blade 320 is formed to have a diameter of 10 to 50 cm from the upper end side of the bearing 121 of the rotating portion, Wherein the impeller is formed so as to be disposed within the gap.

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