KR200497439Y1 - Automatic input apparatus for polymer coagulant for wastewater treatment - Google Patents

Abstract

In the present invention, a storage space is formed where a polymer flocculant in powder form used in wastewater treatment can be stored, and the polymer flocculant placed in the storage space is moved to the lower part by gravity, and the lower part is where the polymer flocculant is stored. When the polymer coagulant stored in the storage space of the coagulant storage tank moves to the lower part of the coagulant storage tank and is arranged in the vertical direction in the coagulant storage tank and the coagulant storage tank is formed with an outlet so that it can be discharged, the polymer coagulant is stored at a set capacity. It provides an automatic polymer coagulant dispensing device that includes a screw feeder that rotates at a set rotation amount so that it discharges through the outlet and falls by gravity.
Therefore, when discharging the polymer coagulant by rotating the screw feeder, there is an advantage that the discharge amount of the polymer coagulant can be accurately discharged at a set amount by adjusting the rotation angle of the screw feeder.

Description

Automatic input apparatus for polymer coagulant for wastewater treatment}

The present invention relates to an automatic polymer flocculant injection device for wastewater treatment, and more specifically, to an automatic polymer flocculant injection device for wastewater treatment that adjusts the rotation angle of the screw feeder to discharge a certain amount of polymer flocculant in the direction of gravity. will be.

In general, water treatment facilities collect raw water and then go through processes of mixing, coagulation, sedimentation, and filtration. Among these, the flocculation process is a process in which a coagulant is added to the water to coagulate even fine particles such as suspended substances, organic matter, and microorganisms in the water into a lump state, that is, a floc state. Depending on the efficiency of the flocculation process, subsequent processes and treated water quality are affected. It has a significant impact.

For this coagulation process, an organic polymer coagulant is added at a wastewater treatment plant, but there is the inconvenience of having to add the coagulant once an hour. Currently, large-scale public sewage treatment facilities use automatic injectors to treat wastewater. However, small-scale wastewater plants do not have automatic coagulant injection devices, so there is the inconvenience of workers having to add coagulant every hour. Accordingly, by installing an automatic injector, there is a need to switch to an automated method that only requires charging raw materials about once a day without the difficulty of injecting coagulant every hour.

Additionally, due to the nature of organic polymer coagulants, they tend to react with moisture in the air and cause entanglement. In this case, there is a problem that the efficiency of the coagulant is reduced. Therefore, in order to prevent entanglement of the coagulant, it is necessary to control the humidity of the device that supplies the coagulant.

Republic of Korea Patent No. 10-1523471

The purpose of the present invention is to provide an automatic polymer coagulant injection device for wastewater treatment that can discharge a certain amount of polymer coagulant in the direction of gravity by adjusting the rotation angle of the screw feeder being combined.

According to one aspect of the present invention, a storage space is formed in which a polymer flocculant in powder form used for wastewater treatment can be stored, and the polymer flocculant disposed in the storage space is moved downward by gravity. , the lower part is disposed in the vertical direction in the coagulant storage tank and the coagulant storage tank in which an outlet is formed so that the polymer coagulant can be discharged, and the polymer coagulant stored in the storage space of the coagulant storage tank moves to the lower part of the coagulant storage tank. Then, an automatic polymer coagulant dispensing device is provided including a screw feeder that rotates at a set rotation amount so that the polymer coagulant is discharged at a set volume through the outlet and falls by gravity.

The automatic polymer flocculant injection device for wastewater treatment according to the present invention has the following effects.

First, when discharging the polymer coagulant by rotating the screw feeder, there is an advantage that the discharge amount of the polymer coagulant can be accurately discharged at a set amount by adjusting the rotation angle of the screw feeder.

Second, since the screw feeder is arranged in the vertical direction, the polymer coagulant naturally moves downward due to gravity, which has the advantage of saving energy for moving the polymer coagulant.

Third, a humidity measurement sensor is installed in the air flow pipe that allows the air inside the coagulant storage tank to be discharged to the outside and then flow back into the coagulant storage tank, so that the humidity inside the coagulant storage tank can be known without directly measuring the humidity inside the coagulant storage tank. There are advantages to this.

Fourth, when the humidity measured by the humidity measurement sensor exceeds the set humidity, the dehumidifier installed in the air flow pipe has the advantage of controlling the humidity inside the coagulant storage tank by removing moisture inside the air flow pipe.

Figure 1 is a schematic diagram of an automatic polymer coagulant injection device for wastewater treatment according to an embodiment of the present invention.
Figure 2 is a schematic diagram showing the screw feeder of the automatic polymer flocculant injection device for wastewater treatment according to Figure 1 separated.
Figure 3 is a schematic diagram showing how the screw feeder of the automatic polymer flocculant injection device for wastewater treatment according to Figure 1 rotates at a set angle and discharges a certain amount of polymer flocculant.
Figure 4 is a block diagram showing the configuration included in the motor that rotates the screw feeder in the automatic polymer coagulant injection device for wastewater treatment according to Figure 1.

Hereinafter, the present invention will be described in detail by explaining preferred embodiments of the present invention with reference to the attached drawings.

Referring to Figures 1 to 4, the automatic polymer flocculant injection device 100 for wastewater treatment according to an embodiment of the present invention includes a flocculant storage tank 110, a screw feeder 120, a motor 130, and an air flow pipe 140. , an air circulation fan 150, a humidity measurement sensor 160, a dehumidifier 170, and a control unit (not shown). The automatic polymer flocculant injection device 100 for wastewater treatment according to this embodiment allows the polymer flocculant to be charged into the flocculant storage tank 110 and automatically discharge a set amount of the polymer flocculant at a set time.

The coagulant storage tank 110 provides a space where a polymer coagulant in powder form used for wastewater treatment is stored. In this embodiment, the top of the coagulant storage tank 110 is closed by a lid, and an opening is formed at the bottom so that the polymer coagulant stored therein can be discharged downward. The lid may be formed in a structure that can be opened and closed so that the coagulant can be introduced. However, the present invention is not limited to this, and the top of the coagulant storage tank 110 may also be formed in an open structure.

In this embodiment, the coagulant storage tank 110 is composed of an upper coagulant storage tank 111, a central coagulant storage tank 112, and a lower coagulant storage tank 113. The upper part of the coagulant storage tank 111 has a constant diameter (width) and extends in the vertical direction. And the central part of the coagulant storage tank 112 is a portion extending downward from the bottom of the upper part of the storage tank so that the diameter (width) gradually decreases. And the lower part of the coagulant storage tank 113 is a part extending from the bottom of the central part of the coagulant storage tank 112 to have a certain diameter (width). However, the present invention is not limited to this, and the coagulant storage tank 110 may be composed of only the upper coagulant storage tank 111 and the lower coagulant storage tank 113.

The screw feeder 120 serves to move the polymer coagulant stored in the coagulant storage tank 110 downward. At this time, the screw feeder 120 is arranged in the vertical direction in the coagulant storage tank 110 so that the polymer coagulant naturally moves downward by gravity. And the screw feeder 120 may rotate at a certain angle so that the polymer coagulant is discharged at a set volume. When the screw feeder 120 is fixed without rotating, it serves to close the lower part of the coagulant storage tank 110 so that the polymer coagulant is not discharged from the coagulant storage tank 110.

In this embodiment, the screw feeder 120 extends through the upper part of the coagulant storage tank 110 to the lower part of the coagulant storage tank 120. At this time, for example, the upper part of the screw feeder 120 protrudes above the upper surface of the coagulant storage tank 110 and is connected to the motor 130.

Specifically, the screw feeder 120 includes a rotating shaft 121 and a blade 122. The rotation shaft 121 is a part extending from the upper part connected to the motor 130 to the lower part of the coagulant storage tank 110. And the blade 122 is formed from a lower portion of the outer peripheral surface of the rotation shaft 121 to a portion extending a set length upward. In this embodiment, the blade 122 is formed in the middle part of the flocculant storage tank 112 and the lower part of the flocculant storage tank 113, but the blade 122 may also be formed in the upper part 111 of the flocculant storage tank. . The blade 122 is extended and has a continuous spiral structure.

In this embodiment, the screw feeder 120 is made of polyvinyl chloride (PVC) or polyethylene (PE). This is to prevent the screw feeder 120 from being corroded by gas generated from the wastewater when the water treatment device (A) containing wastewater is placed below the screw feeder 120.

The motor 130 is installed in the coagulant storage tank 110. In this embodiment, the motor 130 is a DC motor with low power consumption and detailed speed control, but the type of the motor 130 can be changed.

In this embodiment, the motor 130 is placed at the top of the coagulant storage tank 110 as an example, but the installation location of the motor 130 can be changed as much as desired. The motor 130 serves to rotate the screw feeder 120 at a set angle so that the polymer coagulant is discharged at a set volume. That is, the motor 130 connected to the screw feeder 120 adjusts the rotation amount of the screw feeder 120, thereby controlling the amount of the polymer coagulant discharged by the screw feeder 120. That is, when the motor 130 rotates the screw feeder 120 at a certain angle, the polymer coagulant is discharged from the coagulant storage tank 110 in a constant amount by the screw feeder 120.

However, the present invention is not limited to this, and the motor 130 may include an angle measuring unit 131 and a rotation speed measuring unit 132. In this case, the angle measuring unit 131 measures the rotation angle of the screw feeder 120 when the motor 130 rotates the screw feeder 120. This is to accurately represent the rotation angle when the screw feeder 120 rotates less than one rotation.

The rotation speed measuring unit 132 measures the rotation speed of the screw feeder 120. That is, the rotation speed measuring unit 132 indicates how many rotations the screw feeder 120 is rotating.

Each time the screw feeder 120 rotates once, the angle measuring unit 131 is reset to 0 degrees, and each time the angle measuring unit 131 is reset, the rotation speed measuring unit 132 rotates by 1. increases. In this embodiment, the angle measuring unit 131 and the rotation speed measuring unit 132 each include a display indicating the rotation angle or rotation speed. However, the present invention is not limited to this, and the angle measured by the angle measuring unit 131 and the rotation speed of the screw feeder 120 measured by the rotation speed measuring unit 132 can be displayed together on a separately installed display.

Although not shown in the drawing, the motor 130 may further include a lamp that displays the rotation angle and number of rotations of the screw feeder 120 in color. The lamp changes color while the screw feeder 120 rotates once. Specifically, when the screw feeder 120 starts rotating, the lamp gradually changes from a light first color to a dark first color. And when the screw feeder 120 makes one rotation, it changes to white. And when the screw feeder 120 starts rotating again, the light second color, which is different from the first color, changes to a dark second color. At this time, the color changes from the first color to the second color... to the n-th color, and the change order of the first color to the n-th color is determined, so the screw feeder 120 changes depending on the color change. You can visually check whether it is in a rotating state.

The air flow pipe 140 provides a path through which air existing in the surroundings can flow in through one side and then be discharged to the periphery of the coagulant storage tank through the other side. That is, the air flow pipe 140 introduces air existing around the coagulant storage tank 110 through one side and then discharges it back around the coagulant storage tank 110. The air flow pipe 140 has a hollow interior through which air can flow. In this embodiment, the air flow pipe 140 has a rectangular parallelepiped shape as an example, but the shape of the air flow pipe 140 can be changed at any time.

And the air flow pipe 140 is arranged to surround all or part of the portion of the coagulant storage tank 110 where the screw feeder 120 is disposed. That is, the air flow pipe 140 may serve to prevent condensation, etc. from occurring in the lower part of the coagulant storage tank 113. In addition, the air flow pipe 140 serves to block moisture evaporated from the hydraulic device (A) disposed below the coagulant storage tank 110 from moving directly toward the upper part of the coagulant storage tank 110. Accordingly, the air flow pipe 140 may be formed to have a wider width than the water treatment device (A).

Specifically, the air flow pipe 140 has a vertical fitting hole formed in the center so that the coagulant storage tank 110 can be inserted from the top to the bottom and mounted on the air flow pipe 140.

In this embodiment, the fitting hole includes a first region, a second region, and a third region that are sequentially formed from top to bottom. The first region is a portion having a constant diameter from top to bottom. The inside of the first area is in close contact with the outside of the upper part of the coagulant storage tank (111). And the second region is formed below the first region and has a smaller diameter than the first region. And the diameter of the second region becomes narrower from the top to the bottom. The inside of the second area is in close contact with the outside of the central part of the coagulant storage tank (112). The third area is formed below the second area and has the same diameter as the lower end of the second area. And the third region has a constant diameter from top to bottom. And the inside of the third area is in close contact with the outside of the lower part of the coagulant storage tank 113.

And an air outlet 141 is formed at the top of the air flow pipe 140. The dried air that flows into the air flow pipe 140 through the air outlet 141 is discharged. At this time, the air outlet 141 is formed at the upper part of the air flow pipe 140, so that the dried air is discharged upward where the coagulant storage tank 110 is disposed, thereby discharging the dry air from the air around the coagulant storage tank 110. Specific gravity increases, and the possibility of moisture flowing into the coagulant storage tank 110 is reduced.

The air circulation fan 150 is installed in the air flow pipe 140. The air circulation fan 140 introduces air around the coagulant storage tank 110 into the air flow pipe 140, and moves the air introduced into the air flow pipe 140 to the outside of the air flow pipe 140. Let it be discharged. That is, the air circulation fan 150 allows air surrounding the coagulant storage tank 110 to flow into the air flow pipe 140, then flows inside the air flow pipe 140 and out of the air flow pipe 140. It serves to circulate the air around the coagulant storage tank 110 by allowing it to be discharged.

The humidity measurement sensor 160 is installed in the air flow pipe 140. The humidity measurement sensor 160 measures the humidity of the air flowing through the air flow pipe 140 by the air circulation fan 150. However, the present invention is not limited to this, and the humidity measurement sensor 160 can also measure the humidity of surrounding air adjacent to the air flow pipe 140. In this embodiment, the humidity measurement sensor 160 is placed at the top of the air flow pipe 140 as an example.

The dehumidifier 170 is installed in the air flow pipe 140. The dehumidifier 170 lowers the humidity around the coagulant storage tank 110 when the humidity measured by the humidity measurement sensor 160 exceeds the set humidity, thereby lowering the humidity of the coagulant storage tank 110. It serves to remove moisture from the air flowing through the flow pipe 140.

The control unit (not shown) is connected to the motor 130, the air circulation fan 150, the humidity measurement sensor 160, and the dehumidifier 170 through a wired or wireless network, respectively. The control unit controls the operation of the motor 130 to control the rotation of the screw feeder 120, thereby controlling the discharge of the polymer coagulant stored in the coagulant storage tank 110. At this time, the control unit controls the rotation of the screw feeder 120 by controlling the rotation of the motor 130 so that the polymer coagulant is discharged at a set volume.

And the control unit controls the operation of the air circulation fan 150 to control the flow of air inside the air flow pipe 140. And the control unit controls the operation of the humidity measurement sensor 160 to control the humidity of the air flowing into the air flow pipe 140 from the outside of the air flow pipe 140 corresponding to the periphery of the coagulant storage tank 110. Measure.

And the control unit causes the dehumidifier 170 to remove moisture from the humid air flowing into the air flow pipe 140 and then discharge dry air back to the air flow pipe 140. Through this, the humidity inside the coagulant storage tank 110 is lowered to reduce the inflow of moisture into the coagulant storage tank 110, thereby controlling the humidity inside the coagulant storage tank 110.

For convenience of illustration, the humidity measurement sensor 160 and the dehumidifier 170 are shown as being disposed outside the air flow pipe 140, but the humidity measurement sensor 160 and the dehumidifier 170 are located outside the air flow pipe ( 140) may be placed inside. In this embodiment, the air outlet 141, the air circulation fan 150, the humidity sensor 160, and the dehumidifier 170 are each formed one by one, but the air outlet 141 and the air The circulation fan 150, the humidity sensor 160, and the dehumidifier 170 may each be formed in plural numbers. In this embodiment, the lower part of the coagulant storage tank 113 protrudes downward from the air flow pipe 140, but the lower end of the lower coagulant storage tank 113 forms a flat surface with the lower end of the air flow pipe 140. It may be.

To briefly explain the process of lowering the humidity inside the coagulant storage tank 110, air around the coagulant storage tank 110 is introduced into the air flow pipe 140 by the air circulation fan 150, and the air flow pipe 140 The humidity measurement sensor 160 measures the humidity of the air flowing into the air. And information about the humidity measured by the humidity measurement sensor 160 is transmitted to the control unit. And when the humidity measured by the humidity measurement sensor 160 exceeds the set humidity, the control unit operates the dehumidifier 170 to remove moisture from the air flowing through the air flow pipe 140.

When the humidity measurement sensor 160 and the dehumidifier 170 are placed outside the air flow pipe 140, the air around the coagulant storage tank 110 is transferred to the air flow pipe 140 by the air circulation fan 150. The humidity measurement sensor 160 measures the humidity of the air flowing into the air flow pipe 140. And information about the humidity measured by the humidity measurement sensor 160 is transmitted to the control unit. And when the humidity measured by the humidity measurement sensor 160 exceeds the set humidity, the control unit operates the dehumidifier 170 to remove moisture from the air flowing into the air flow pipe 140.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims.

100: Automatic polymer coagulant injection device
110: Flocculant storage tank
120: screw feeder
130: motor
140: air flow pipe
150: Air circulation fan
160: Humidity measurement sensor
170: Dehumidifier

Claims (11)

A storage space is formed where a polymer flocculant in powder form used for wastewater treatment can be stored, and the polymer flocculant placed in the storage space is moved to the lower part by gravity, and the lower part is where the polymer flocculant can be discharged. A coagulant storage tank having an outlet so as to provide a coagulant storage tank; and
When the polymer coagulant disposed in the vertical direction in the coagulant storage tank and stored in the storage space of the coagulant storage tank moves to the lower part of the coagulant storage tank, the polymer coagulant is discharged at a set volume through the outlet and falls by gravity. It includes a screw feeder that rotates at a set rotation amount,
Provides a path through which air existing in the surroundings can flow in and flow through one side and then be discharged to the periphery of the coagulant storage tank through the other side, and surrounds all or part of the portion of the coagulant storage tank where the screw feeder is disposed. an air flow pipe disposed;
an air circulation fan installed in the air flow pipe, allowing air surrounding the coagulant storage tank to flow into the air flow pipe, circulating the air introduced into the air flow pipe, and discharging it to the outside of the air flow pipe; and
Further comprising a humidity measurement sensor installed in the air flow pipe and measuring the humidity of the air flowing through the air flow pipe by the air circulation fan,
Automatic polymer coagulant injection device. delete In claim 1,
It is installed in the air flow pipe, and when the humidity measured by the humidity measurement sensor exceeds the set humidity, moisture in the air flowing through the air flow pipe is removed to lower the humidity of the coagulant storage tank by lowering the surrounding humidity of the coagulant storage tank. Further comprising a dehumidifier that removes,
Automatic polymer coagulant injection device. In claim 3,
Connected to the air circulation fan, the humidity measurement sensor, and the dehumidifier through a wired or wireless network, respectively, and further comprising a control unit that controls operations of the air circulation fan, the humidity measurement sensor, and the dehumidifier,
Automatic polymer coagulant injection device. In claim 1,
It is installed in the flocculant storage tank and further comprises a motor that rotates the screw feeder at a set rotation amount so that the polymer flocculant is discharged at a set volume.
Automatic polymer coagulant injection device. In claim 5,
Further comprising a control unit connected to the motor through a wired or wireless network,
The control unit,
Controlling the rotation amount of the motor so that the polymer coagulant is discharged at a set volume,
Automatic polymer coagulant injection device. In claim 5,
The motor is disposed at the top of the flocculant storage tank,
The screw feeder is,
It extends through the upper part of the coagulant storage tank to the lower part of the coagulant storage tank, and the upper part protrudes above the upper surface of the coagulant storage tank and is connected to the motor,
Automatic polymer coagulant injection device. In claim 7,
The screw feeder is,
a rotating shaft extending from the upper part connected to the motor to the lower part of the coagulant storage tank; and
A set length extends upward from the lower portion of the outer peripheral surface of the rotating shaft and is disposed in the lower and middle portions of the coagulant storage tank, comprising a blade extending while having a continuous spiral structure,
Automatic polymer coagulant injection device. In claim 1,
A water treatment device containing wastewater is disposed below the screw feeder,
The screw feeder is,
Made of polyvinyl chloride material or polyethylene material to prevent corrosion by gases generated from wastewater contained in the water treatment device,
Automatic polymer coagulant injection device. In claim 4,
Surrounding air is introduced into the air flow pipe by the air circulation fan, the humidity measurement sensor measures the humidity of the air flowing into the air flow pipe, and information about the humidity measured by the humidity measurement sensor is provided in the It is transmitted to the control unit, and when the humidity measured by the humidity measurement sensor exceeds the set humidity, the control unit operates the dehumidifier to remove moisture from the air flowing inside the air flow pipe.
Automatic polymer coagulant injection device. In claim 1,
The air flow pipe is,
A vertical insertion hole is formed in the center so that the coagulant storage tank can be inserted and mounted from the top to the bottom,
The insertion hole is,
A first region having a constant diameter from top to bottom;
a second region formed below the first region, having a smaller diameter than the first region, and narrowing in diameter from the top to the bottom; and
It is formed in the lower part of the second area, has the same diameter as the lower end of the second area, and has a constant diameter from the top to the bottom,
Automatic polymer coagulant injection device.

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