KR101268710B1 - A device for throwing powder into water of a filtration plant - Google Patents

Abstract

The present invention, in the water treatment powder storage supply device for injecting the water treatment powder for water treatment in the water treatment plant, the upper end is formed with a supply port for the inlet of the water treatment powder, the lower end of the storage formed with an outlet for the discharge of the water treatment powder It is installed to be perpendicular to the bottom of the storage housing into the housing, the storage housing, the outer surface is formed with a plurality of guide plates inclined to be spaced apart from each other in the circumferential direction to slide the water treatment powder introduced into the storage housing to the outlet A stirring housing provided with a stirring shaft provided with a stirring blade provided with a stirring blade so as to be discharged after receiving the water treatment powder from the guide, the storage housing and discharged to the inside of the storage housing. It is connected to the stirring shaft and generates driving force to rotate the stirring shaft. Provides a water treatment powder storage units for which a stirring unit for driving.
As such, the water treatment powder storage supply device, the water treatment powder storage supply device, the water treatment powder stored in the storage housing is transported slidingly through the inside of the powder guide and the guide plate, the stirring of the stirring shaft again in the state of being put into the stirring housing While stirring by the rotation of the blade can prevent the deposition phenomenon by consolidation, it is possible to stably feed the water treatment powder to the water treatment plant.

Description

A device for throwing powder into water of a filtration plant}

The present invention relates to a powder storage supply device for water treatment, and more particularly, to a powder storage supply device for water treatment injecting powdered chemicals used for water treatment in a water treatment plant.

In general, water treatment plants in water and sewage facilities inject chemicals for water treatment. In the water treatment, powder activated carbon, slaked lime, polymer agglomerates, and the like are added to the water treatment to increase the water treatment effect. In other words, water purification facilities of water supply sources are injecting necessary powders to remove contaminants contained in raw water or to aggregate and remove solids.In addition, powders for removing pollutants and odors are removed from sewage treatment plants. Will be committed. At this time, the powder for water treatment is made in the state supplied to the hopper.

However, in such a water treatment plant, by supplying the powder of 1 to 7 days in the state stored in the hopper consisting of a vertical storage structure of a single structure, the fluidity is reduced along with the deposition by consolidation of the powder, the arching ( There is a problem in that a stable supply from the hopper to the water treatment plant is not achieved due to arching or bridging.

It is an object of the present invention to provide a water treatment powder storage and supply device which can stably supply water treatment powder to a water treatment plant during water treatment.

The present invention, in the water treatment powder storage supply device for injecting the water treatment powder for water treatment in the water treatment plant, a supply port for the inlet of the water treatment powder is formed at the upper end, the outlet for discharging the water treatment powder is And a plurality of guide plates inclined so as to slide and transport the water treatment powder introduced into the storage housing to the outlet, the storage housing being formed so as to be perpendicular to the bottom of the storage housing inside the storage housing. A powder guide formed to be spaced apart from each other in a direction, and installed in a lower portion of the storage housing so as to be discharged after receiving the water treatment powder from the storage housing, and the water treatment powder supplied therein can be discharged under stirring. Stirring housing equipped with a stirring shaft provided with a stirring blade so that And, is provided connected to the stirring shaft, provides a powder storage supply device for water treatment comprising a stirring drive unit for generating a driving force to rotate the stirring shaft.

In addition, the powder guide has a tubular shape that is open at both ends to slide the water treatment powder to the discharge port, at least one dispersion plate is formed in the powder guide inclined from the upper end to the lower end, the powder guide inside The water treatment powder passing through the collision with the dispersion plate can be transported in a dispersed state.

In addition, the stirring drive unit is connected to the stirring motor for generating a rotational drive force, the rotating shaft and the stirring shaft of the stirring motor, the speed reducer to be transmitted to the stirring shaft in a state in which the rotational speed of the stirring motor is reduced It may include.

In addition, the stirring shaft is disposed between the discharge port and the stirring blade, the partition for allowing the water treatment powder received from the discharge port to be divided into the stirring housing while being rotated in response to the shaft rotation of the stirring shaft. It may further comprise a split discharge plate formed.

In addition, the split discharge plate is provided with a collision protrusion having a ductile to protrude upward, the collision protrusion may collide with the lower end of each of the guide plate when the corresponding rotation with respect to the axial rotation of the stirring shaft.

The apparatus may further include a rotary valve installed under the stirring housing to receive the water treatment powder from the stirring housing and to discharge the water treatment powder to the water treatment plant in a fixed state.

The rear surface of the guide plate may further include a heating pad for drying the water treatment powder while heating the guide plate to prevent aggregation of the water treatment powder by water.

Water treatment powder storage supply apparatus according to the present invention, the water treatment powder stored in the storage housing is conveyed slidingly through the powder guide inside and the guide plate, and then consolidated while stirring by rotating the stirring blades of the stirring shaft again in the state entered into the stirring housing. It is possible to prevent the deposition phenomenon by the bar, it is possible to stably add the water treatment powder to the water treatment plant.

1 is a schematic configuration diagram of a powder storage supply device for water treatment according to an embodiment of the present invention.
FIG. 2 is a schematic perspective view of the storage housing shown in FIG. 1. FIG.
3 is a sectional view taken along the line III-III in Fig.
4 is a plan view of the splitter discharge plate shown in FIG. 1.
5 is an installation state diagram of FIG. 4.
6 is a plan sectional view of the main body of the rotary valve shown in FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 is a schematic configuration diagram of a powder storage supply device for water treatment according to an embodiment of the present invention, Figure 2 is a schematic perspective view of the storage housing shown in FIG. 1 and 2, the powder storage supply device for water treatment includes a storage housing 100, a powder guide 200, a stirring housing 300, and a stirring driving unit 400.

The storage housing 100 is a cylindrical member having a space therein so as to store the water treatment powder to be introduced into a water treatment plant (not shown) and then supply it to the stirring housing 300 which will be described later. The supply opening 110 is formed at the upper end of the storage housing 100 to inject the water treatment powder therein. In addition, a discharge port 120 is formed at a lower end of the storage housing 100 so that the water treatment powder introduced into the container 110 through the supply port 110 may be discharged to the stirring housing 300 which will be described later.

The powder guide 200 guides the water treatment powder injected into the storage housing 100 to be discharged to the stirring housing 300 through the outlet 120 while slidingly transporting the water treatment powder at a constant speed. That is, the powder guide 200 allows the water treatment powder introduced into the storage housing 100 through the supply port 110 to be slidably transported so that deposition by consolidation does not occur.

The powder guide 200 has a tubular shape in which both ends in the longitudinal direction are opened so as to slide the water treatment powder to the discharge port 120. The powder guide 200 is installed in the center of the storage housing 100 in a state perpendicular to the bottom of the storage housing 100.

In addition, the powder guide 200 may be provided with at least one dispersion plate 220 to collide with the water treatment powder passing therethrough, and to transport the water treatment powder in a dispersed state. The water treatment powder conveyed into the powder guide 200 into the dispersion plate 220 collides with each other, and the water treatment powder is discharged through the outlet 120 in a state in which the vertical compressive stress of the water treatment powder is dispersed. To be possible. Here, the dispersion plate 220 is formed to be inclined in the direction from the top to the bottom so that the water treatment powder can be slidingly transported downward without accumulating on the top in the state of impinging the water treatment powder.

In addition, a plurality of guide plates 210 are formed on the outer surface of the powder guide 200 to guide the water treatment powder introduced into the storage housing 100 to be slidably transported to the outlet 120. Such, the guide plate 210 is formed to be inclined in the direction from the top to the bottom on the outer surface of the powder guide 200. That is, the guide plates 210 may be formed in a helical structure with an angle of repose that allows the water treatment powder to be slidably transported to the outlet 120 on the outer surface of the powder guide 200. Here, the guide plates 210 are formed to be spaced apart at regular intervals from each other with respect to the circumferential direction of the powder guide 200.

In addition, the front surface of the guide plate 210, that is, the surface portion for sliding the water treatment powder may be surface treatment so that the water treatment powder can be easily transported.

As shown in FIG. 3, a heating pad 211 may be attached to the rear surface of the guide plates 210, that is, the opposite surface of the sliding feed surface of the water treatment powder, to heat the guide plates 210. . This, the heating pad 211 is to heat the guide plate 210 to the heating state, and to dry the water treatment powder to be transferred to the guide plate 210 front surface, the water treatment powder is agglomerated by moisture It can be prevented. Here, the heating pad 211 has a well-known structure that generates heat when the power is supplied from the outside, the description of the detailed structure is omitted.

The stirring housing 300 is a cylindrical member having a space therein so that the water treatment powder discharged through the powder guide 200 and then the water treatment powder discharged through the outlet 120 is introduced. The first connector 310 is formed at the upper end of the stirring housing 300 so as to communicate with the outlet 120 of the storage housing 100. In addition, a second connector 320 is formed at a lower end of the stirring housing 300 to discharge the water treatment powder introduced into the inside through the first connector 310 to the outside.

Then, the water treatment powder is the stirring housing 300 while stirring and transporting the water treatment powder supplied and stored upward from the storage housing 100 through the first connector 310 to the inside of the stirring housing 300. ) Is provided with a stirring shaft 330 to prevent the occurrence of deposition due to consolidation inside. That is, the stirring shaft 330 keeps the water treatment powder in the stirring housing 300 in a dusty state without being deposited, so that the water treatment powder can be discharged in a powder state of a constant density.

The stirring shaft 330 is installed to be rotatable in a vertically disposed state in the stirring housing 300. In addition, a stirring blade 340 is provided in the axial direction of the stirring shaft 330 to transfer and stir the water treatment powder in the stirring housing 300 upward according to the axial rotation of the stirring shaft 300. . As such, the stirring blade 340 formed on the stirring shaft 330 is introduced into the stirring housing 300, and then maintained in the powder state while moving the accumulated water treatment powder upward.

In addition, the stirring shaft 330 may be provided with a plate-shaped split discharge plate 350 to be located between the outlet 120 of the storage housing 100 and the stirring blade 340. The split discharge plate 350 corresponds to the rotation of the stirring shaft 330 while the water treatment powder discharged through the outlet 120 is not introduced into the stirring housing 300 in a predetermined amount. Allow split inflow. That is, the split discharge plate 350 allows the water treatment powder discharged through the outlet 120 of the storage housing 100 to be introduced into the stirring housing 300 several times without being supplied all at once, It is possible to prevent the overload is applied to the stirring blade 340.

Referring to FIG. 4, a splitter 351 is formed at one side of the split discharge plate 350 to allow the water treatment powder discharged from the discharge port 120 to be introduced into the stirring housing 300. As such, the split discharge plate 350 is provided with the stirring shaft 330 to rotate in correspondence with the rotation of the stirring shaft 330, while the storage housing 100 rotates corresponding to the rotation of the stirring shaft 330. The amount of the water treatment powder is smaller than the amount discharged through the outlet 120 of the inlet) is introduced into the stirring housing 300 through the partition 351.

In addition, referring to Figure 5, one side of the split discharge plate 350 may be provided with a collision protrusion 352 to protrude upward. The collision protrusion 352 collides with the lower end of the guide plate 210 of the powder guide 200 when the split discharge plate 350 rotates to correspond to the rotation of the stirring shaft 330. That is, the collision protrusion 352 causes the vibration on the guide plate 210 and the powder guide 200 while colliding with the guide plate 210 when the stirring shaft 330 rotates, Through the guide plate 210 and the powder guide 200 inside the water treatment powder can be easily transported sliding. Here, the collision protrusion 352 is formed of a rubber or synthetic resin material having a ductility so as to prevent damage to the guide plate 210 when it collides with the guide plate 210.

The stirring drive unit 400 generates a driving force to allow the stirring shaft 330 to rotate in the stirring housing 300. Such, the stirring drive unit 400 is installed connected to the shaft end of the stirring shaft 330. Here, the stirring drive unit 400 includes a stirring motor 410, a reducer 420.

The stirring motor 410 generates a rotational driving force to rotate the stirring shaft 330. The rotation shaft end of the stirring motor 410 is connected to the speed reducer 420 to transmit the rotational force to the speed reducer 420.

The reducer 420 transmits the rotational force of the stirring motor 410 to the stirring shaft 330. At this time, the reducer 420 is transmitted to the stirring shaft 330 in a state in which the rotational speed generated by the stirring motor 410 is reduced, so that the stirring shaft 330 of the rotating shaft of the stirring motor 410 Allows the shaft to rotate at a speed slower than the rotation speed. The speed reducer 420 is disposed between the stirring motor 410 and the stirring shaft 330, and is connected to the rotary shaft of the stirring motor 410 and the shaft end of the stirring shaft 330. Here, the speed reducer 420 is disposed to be connected to the lower end of the stirring shaft 330 according to an embodiment, but it is not limited thereto.

In addition, a rotary valve 500 may be installed at a lower portion of the stirring housing 300 to allow the water treatment powder discharged through the second connector 320 to be constantly introduced into the water treatment plant in a fixed amount. The rotary valve 320 is connected to the second connector 320 of the stirring housing 300. Referring to FIG. 6, the rotary valve 400 is a generally known rotary valve structure, and includes a main body 510 and a rotor 520.

The main body 510 is a cylindrical member having a space so as to be discharged to the water treatment plant after the water treatment powder discharged from the second connector 320 of the stirring housing 300 is introduced. The inlet 511 is formed at one side of the upper surface of the main body 510 to receive the water treatment powder discharged from the second connector 320 of the stirring housing 300. In addition, an inlet 512 is formed at one side of the lower surface of the main body 510 so that the water treatment powder introduced into the water through the inlet 511 may be discharged into the water treatment plant.

The rotor 520 is rotatably installed in a state vertically disposed in the main body 510, and the water treatment powder introduced into the main body 510 through the inlet 511 opens the inlet 512. Through the quantitative state. The rotor 520 is formed with a plurality of distribution blades 530 spaced apart at regular intervals in the circumferential direction. Here, at least five distribution blades 530 are formed to stably inject the water treatment powder introduced into the main body 510 into the water treatment plant in a constant quantitative state while rotating horizontally.

In addition, the rotary valve 530 may be provided with a distribution motor 540 as a driving means for rotating the rotor 520. That is, the rotary shaft of the distribution motor 540 is connected to the end of the rotor 520 to transmit the rotational force to rotate or provided with a separate gear box (not shown) to power the distribution motor 540. The rotor 520 may be transmitted and rotated.

Referring to Figures 1 to 6 the operation of the water treatment powder storage supply apparatus according to an embodiment configured as described above are as follows.

First, the water treatment powder to be introduced into the water treatment plant through the supply port 110 of the storage housing 100 is supplied. As such, when the water treatment powder is supplied into the storage housing 100, the water treatment powder of the storage housing 100 is provided through the inside of the powder guide 200 and the guide plate 210 of the powder guide 200. Sliding downwards. Here, when the water treatment powder in the storage housing 100 is transferred through the inside of the powder guide 200, the dispersion due to the collision with the dispersion plate 220 and the guide plate outside the powder guide 200 ( Sliding transfer to the sliding state through the 210 is prevented from occurring deposition due to consolidation.

As such, the water treatment powder in the storage housing 100 is slid and transported through the powder guide 200 and the guide plate 210, and then transported to the stirring housing 300 through the outlet 120. do.

At this time, the stirring shaft 330 is axially rotated in the stirring housing 300 through the stirring drive unit 400. As such, when the stirring shaft 330 is axially rotated in the stirring housing 300, the water treatment powder introduced into the stirring housing 300 is stirred by the stirring blade 340 of the stirring shaft 330. While stirring to be transferred upward, the water treatment powder prevents the deposition phenomenon due to consolidation in the stirring housing 300.

Thereafter, the water treatment powder in the stirring housing 300 is constantly discharged to the rotary valve 500 as a powder state having a disturbed fluidity without consolidation as it is stirred by the rotation of the stirring shaft 330.

As such, the water treatment powder, which is in a powder state, is introduced into the main body 510 through the inlet 511 formed in the main body 510 of the rotary valve 500. Then, the water treatment powder in the main body 510 is quantified by the dispensing blade 530 of the rotor 520 rotating in the main body 510 through the inlet 512. After being discharged from, the input to the water treatment plant is made.

As described above, the water treatment powder storage supply apparatus of one embodiment, after the water treatment powder to be stored in the storage housing 100 is transported through the powder guide 200 and the guide plate 210, the While being stirred by the stirring blades 210 of the stirring shaft 330 again while being introduced into the stirring housing 300, the sedimentation phenomenon due to consolidation can be prevented and the water treatment powder can be stably added to the water treatment plant. It becomes possible.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: storage housing 110: supply port
120: outlet 200: powder guide
210: guide plate 211: heating pad
220: dispersion plate 300: stirring housing
310: first connector 320: second connector
330: stirring shaft 340: stirring blade
350: split discharge plate 351: split mouth
352: impingement projection 400: stirring drive unit
410: stirring motor 420: reducer
500: rotary valve 510: main body
520: rotor 530: distribution wing
540: distribution motor

Claims (7)

In the water treatment powder storage and supply device for injecting the water treatment powder for water treatment in the water treatment plant,
A storage housing formed at an upper end thereof with a supply hole for inflow of the water treatment powder, and a lower end having a discharge hole for discharging the water treatment powder;
The storage housing is installed so as to be perpendicular to the bottom of the storage housing, a plurality of guide plates inclined so as to slide the water treatment powder introduced into the storage housing to the outlet in the outer surface spaced apart from each other in the circumferential direction A powder guide so formed;
It is installed in communication with the lower portion of the storage housing to be discharged after receiving the water treatment powder from the storage housing, the inside is equipped with a stirring shaft provided with a stirring shaft provided with a stirring blade to discharge the water treatment powder supplied to the stirring state housing; And
It is connected to the stirring shaft, including a stirring drive unit for generating a driving force to rotate the stirring shaft,
The powder guide has a tubular shape that is open at both ends to slide the water treatment powder to the discharge port.
At least one dispersion plate is formed in the powder guide inclined in the direction from the top to the bottom, so that the water treatment powder passing through the inside of the powder guide collides with the dispersion plate and is transported in a dispersed state. In the water treatment powder storage and supply device for injecting the water treatment powder for water treatment in the water treatment plant,
A storage housing formed at an upper end thereof with a supply hole for inflow of the water treatment powder, and a lower end having a discharge hole for discharging the water treatment powder;
The storage housing is installed so as to be perpendicular to the bottom of the storage housing, a plurality of guide plates inclined so as to slide the water treatment powder introduced into the storage housing to the outlet in the outer surface spaced apart from each other in the circumferential direction A powder guide so formed;
It is installed in communication with the lower portion of the storage housing to be discharged after receiving the water treatment powder from the storage housing, the inside is equipped with a stirring shaft provided with a stirring shaft provided with a stirring blade to discharge the water treatment powder supplied to the stirring state housing; And
It is connected to the stirring shaft, including a stirring drive unit for generating a driving force to rotate the stirring shaft,
In the stirring shaft,
It is disposed between the discharge port and the stirring blade, and further comprises a split discharge plate formed with a split port for dividing the water treatment powder received from the discharge port into the stirring housing while rotating correspondingly to the axial rotation of the stirring shaft. Powder storage supply device for water treatment. In the water treatment powder storage and supply device for injecting the water treatment powder for water treatment in the water treatment plant,
A storage housing formed at an upper end thereof with a supply hole for inflow of the water treatment powder, and a lower end having a discharge hole for discharging the water treatment powder;
The storage housing is installed so as to be perpendicular to the bottom of the storage housing, a plurality of guide plates inclined so as to slide the water treatment powder introduced into the storage housing to the outlet in the outer surface spaced apart from each other in the circumferential direction A powder guide so formed;
It is installed in communication with the lower portion of the storage housing to be discharged after receiving the water treatment powder from the storage housing, the inside is equipped with a stirring shaft provided with a stirring shaft provided with a stirring blade to discharge the water treatment powder supplied to the stirring state housing; And
It is connected to the stirring shaft, including a stirring drive unit for generating a driving force to rotate the stirring shaft,
And a heating pad disposed on a rear surface of the guide plate to dry the water treatment powder while heating the guide plate to prevent agglomeration of the water treatment powder by water. 4. The method according to any one of claims 1 to 3,
The stirring drive unit,
A stirring motor for generating a rotational driving force,
And a reducer connected to the rotating shaft of the stirring motor and the stirring shaft to transmit and rotate the rotating shaft of the stirring motor to the stirring shaft in a reduced state. The method according to claim 2,
The split discharge plate is provided with a collision protrusion having a ductile to protrude upward, so that the collision projection collides with the lower end of each of the guide plate during the corresponding rotation with respect to the axial rotation of the stirring shaft. 4. The method according to any one of claims 1 to 3,
And a rotary valve communicating with the lower portion of the stirring housing and receiving the water treatment powder from the stirring housing and discharging the water treatment powder to the water treatment plant in a quantitative state. delete

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