KR20110067433A - Rapid agitate machine and waste water cleaning device - Google Patents

Abstract

PURPOSE: A high speed stirrer and a sewage disposal apparatus including thereof are provided to improve the purification operating speed of sewage, and to minimize the size of the sewage disposal apparatus. CONSTITUTION: A high speed stirrer includes the following: a casing(110) including an inlet(112) and an outlet(114) for passing through sewage; plural additive inlets(120) formed on the circumference of the casing for guiding the insertion of additives to purify the sewage; a stirring unit(130) stirring the additives with the sewage in the high speed; and a sample collection hole(140) capable of opening and closing, installed on the casing for collecting samples from the sewage.

Description

Rapid Stirrer and Wastewater Purification System Equipped with It {RAPID AGITATE MACHINE AND WASTE WATER CLEANING DEVICE}

The present invention relates to a rapid stirrer and a wastewater purification apparatus having the same, and more particularly, to purify wastewater by flowing the wastewater into one casing and injecting different additives in sequence so that each additive is rapidly stirred with the wastewater. It relates to a rapid stirrer which can reduce the working time and the installation space of the equipment.

Conventional wastewater purification and treatment systems for purifying contaminated raw water include intake pumps, first and second chemical treatment tanks, storage tanks, flotation tanks, gas dissolving devices, sludge treatment devices, first and first It consists of 2 treatment chemical storage tanks.

The intake pump takes raw water and pumps it to the first chemical treatment tank. The first chemical treatment tank temporarily stores the raw water pumped from the intake pump and performs the first chemical treatment. In addition, the second chemical treatment tank temporarily stores the raw water supplied from the first chemical treatment tank to the second chemical treatment.

The first and second chemical treatment tanks are connected in communication with the first and second treatment chemical storage tanks, respectively.

The storage tank temporarily stores the first and second chemical treatment water before supplying the first and second chemical treatment water to the flotation tank while sequentially passing through the first and second chemical treatment tanks.

The flotation tank receives the chemical treatment water in the storage tank to float the floats contained in the chemical treatment water, the treated water from which the floats have been removed is discharged, and the collected floats and sludge are stored and dehydrated by the sludge treatment apparatus. Is discharged.

The gas dissolving device sucks a part of the treated water flowing into the floating tank from the storage tank and supplies the microbubble water into the floating tank.

The first and second treatment chemical storage tanks are connected to the first and second chemical treatment tanks, respectively, and the caustic soda is stored as a treatment chemical in the first treatment chemical storage tank, and the second treatment chemical storage tank is PACs are stored as treatment chemicals.

Existing wastewater purification treatment system has a problem in that the installation space of the entire facility is increased because each facility is installed independently, the wastewater is moved in order and the chemical is administered and purified. In addition, the existing waste water purification treatment system has a problem that it takes a long time to purify the waste water because each facility is separated. Therefore, there is a need for improvement.

The present invention has been made in order to improve the above problems, the operation speed of purification of waste water by improving the mixing of each additive and waste water through the impeller after the automatic addition of different additives sequentially or at the same time while flowing waste water in one casing It provides a rapid stirrer and waste water purification apparatus having the same to improve the efficiency, to minimize the waste water purification facilities, to facilitate the replacement of the stirring device such as the impeller provided with a plurality of separable casing. There is a purpose.

The rapid stirrer according to the present invention includes: a casing having an inlet and an outlet for passing the wastewater, and a plurality of openings that can be opened and closed on the circumferential surface so as to be spaced along the axial direction of the casing. And a stirring portion which is formed inside the casing by the number of the additive inlets and rapidly agitates the additives added to the waste water flowing along the axial direction.

The agitator is formed inside the casing and is driven to drive when an external power source is applied, the shaft rotated when the underwater motor is driven, and is formed to rotate together with the shaft to add additives and wastewater introduced into each of the additive inlets. Agitating impeller.

The stirring unit may include: a partition member partitioning the inside of the casing into spaces provided with one additive inlet and forming a flow channel for ensuring the flow of wastewater; and a bracket for detachably supporting the submersible motor with respect to the partition member. Include.

Preferably, the partition member forms a flow concentration guide member to concentrate the wastewater passing through the flow channel to the impeller.

The casing is preferably partitioned by the number of the stirring portion is formed detachably.

The casing preferably forms an openable sampling port for sampling the waste water that has passed through each of the stirring units.

The waste water purification apparatus according to the present invention includes: a sludge storage tank for storing waste water, a rapid stirrer for receiving and discharging the waste water of the sludge storage tank to one side, and an additive for purifying waste water of different components into the rapid stirrer to direct the flow of waste water. According to the present invention, a plurality of additive supply parts are formed to supply to different positions, a filter connected to the other side of the rapid stirrer to filter the suspended solids of the purified waste water, and an operation for supplying the additives of each of the additive supply parts to the waste water from the sludge storage tank. It includes a control unit to control at the same time according to the supply.

The rapid stirrer is provided with an inlet connected to the sludge storage tank and an outlet connected to the filter, the casing through which waste water passes, and is formed to be opened and closed on a circumferential surface so as to be spaced along the axial direction of the casing, and each of the additive supply parts It is provided correspondingly in one-to-one and includes an additive inlet through which the additive is introduced to purify the waste water, and a stirring portion for rapidly stirring the additive added to the waste water flowing along the axial direction by the number of the additive inlets. .

As described above, the rapid stirrer and the waste water purification device having the same according to the present invention, unlike the prior art, by automatically introducing different additives sequentially or simultaneously with the waste water flowing into one casing, and mixing each additive and waste water through the impeller By improving the degree, it is possible to improve the working speed of wastewater purification, minimize the wastewater purification facility, and make the casing separate, thereby facilitating replacement of agitators such as an impeller.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a rapid stirrer and a waste water purification apparatus having the same according to the present invention. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is an installation diagram of a wastewater purification apparatus having a rapid stirrer according to an embodiment of the present invention, Figure 2 is an internal view of a rapid stirrer according to an embodiment of the present invention, Figure 3 is an embodiment of the present invention It is an enlarged view of the stirring part of the rapid stirrer which concerns on the example.

1 to 3, the wastewater purification apparatus according to an embodiment of the present invention is a facility for purifying and neutralizing wastewater flowing in a river or river (pH7 ~ 8), sludge storage tank 10, rapid agitator (100) ), The additive supply unit 20, the filter 30 and the control unit 40.

Sludge storage tank 10 serves to store the waste water flowing in the river, ditch or river. Since this wastewater contains sludge, it is referred to as sludge storage tank 10.

In particular, the sludge storage tank 10 serves to stably supply the waste water by storing the waste water.

The sludge storage tank 10 can be transformed into various shapes and various materials.

At this time, the waste water of the sludge storage tank 10 is located higher than the rapid stirrer 100 can be naturally supplied to the rapid stirrer 100 by the free fall, but forcibly supplied by a certain amount due to the drive of the transfer pump 12 Is preferred.

The sludge storage tank 10 and the transfer pump 12 is preferably connected through a pipe.

On the other hand, the rapid stirrer 100 receives the waste water of the sludge storage tank 10 to one side serves to discharge to the other side.

In addition, the rapid stirrer 100 receives a plurality of additives together with the waste water and provides a space for purifying the waste water by stirring each other.

In addition, the additive supply unit 20 is formed in the plural stirrer 100 to supply a plurality of additives for waste water purification to different locations along the flow progress of the waste water.

Here, the additive supply unit 20 includes a tank for storing the additive and a driving pump 28 for forcibly supplying the additive stored in each tank into the rapid stirrer 100.

At this time, the additives of the same component may be stored in each tank, but it is preferable that additives of different components are stored.

For example, the first tank 22 and the driving pump 28 are connected to one side of the rapid stirrer 100 along the flow direction of the waste water, and the third tank 26 and the driving pump are connected to the other side of the rapid stirrer 100. 28 is connected, the second tank 24 and the driving pump 28 is connected to the central portion of the rapid stirrer 100.

In addition, the caustic soda solution is stored in the first tank 22 as an additive, the zeolite liquid is stored in the second tank 24 as an additive, and the coagulant liquid is stored in the third tank 26 as an additive.

Therefore, the wastewater flowing from one side of the rapid stirrer 100 to the other side exhibits an acidity of about pH 5 to 6.5 due to the caustic soda solution supplied from the first tank 22 and the zeolite liquid supplied from the second tank 24. Due to this, it exhibits an acidity of about pH 6.5 to 7, and exhibits neutrality of about pH 7 to 8 due to the flocculation liquid supplied from the third tank 26, and is purified.

Of course, the additives stored in the first tank 22, the second tank 24, and the third tank 26 may be components different from those described above. In addition, the additives stored in the first tank 22, the second tank 24, and the third tank 26 may all be stored in the same component.

In addition, the number of the first tank 22, the second tank 24 and the third tank 26 is not limited.

On the other hand, the waste water purified by neutralization is preferably discharged to the filter 30 through the other side of the rapid stirrer (100).

That is, the filter 30 serves to filter the suspended matter of the purified waste water discharged from the rapid stirrer 100.

This filter 30 may be of various configurations.

The purified water of the filtered wastewater is recycled, and sludge or suspended matter filtered from the wastewater is preferably disposed of.

In addition, the control unit 40 serves to simultaneously control the operation for supplying the additives of each of the additive supply units 20 depending on whether the waste water is supplied from the sludge storage tank 10.

In other words, the controller 40 is connected to the transfer pump 12, the drive pump 28 connected to the first tank 22, the drive pump 28 connected to the second tank 24 and the third tank 26. The driving pump 28 is controlled.

Thus, a signal for operating the transfer pump 12 to supply wastewater from the sludge storage tank 10 into the rapid stirrer 100 is transmitted to the controller 40, and the controller 40 receives the first tank by the signal. (22), the driving pump 28 connected to each of the second tank 24 and the third tank 26 is controlled to drive simultaneously.

Of course, the controller 40 may control the driving pump 28 connected to each of the first tank 22, the second tank 24, and the third tank 26 in order or selectively with a time difference. .

On the other hand, the rapid stirrer 100 is a facility for stirring the supplied waste water and the additive supplied by the control of the control unit 40, the casing 110, the additive inlet 120 and the stirring unit 130.

The casing 110 forms an outer shape of the rapid stirrer 100 and is applicable to various shapes and various materials.

In particular, the casing 110 has an inlet 112 and an outlet 114.

The inlet 112 serves to receive waste water, and the outlet 114 serves to discharge purified waste water.

In addition, since the waste water is stirred with the additive in the casing 110, the inlet 112 is formed on one side of the casing 110, the outlet 114 of the casing 110 corresponding to the opposite side of the inlet 112 It is preferably formed on the other side.

Then, the inlet 112 is connected to the sludge storage tank 10, the outlet 114 is connected to the filter 30.

In addition, the additive inlet 120 is formed to be opened and closed on the circumferential surface so as to be spaced along the axial direction of the casing 110, and is provided in one-to-one correspondence with each of the additive supply unit 20 to induce the additive to purify the waste water. It plays a role.

In other words, the additive inlet 120 is connected to the first tank 22, the second tank 24, and the third tank 26 of the additive supply unit 20 in a one-to-one correspondence to drive each of the driving pumps 28. It serves to guide the corresponding additives to the inside of the casing (110).

Accordingly, the additive inlet 120 is formed on the circumferential surface of the casing 110 by the number of tanks 22, 24, 26 so as to be spaced apart from one side of the casing 110 along the other direction.

At this time, each of the additive inlet 120 is formed to be opened and closed, depending on whether or not the drive of the drive pump 28 may control the flow of the additive.

Although not shown, each of the additive inlet 120 is preferably opened and closed by a valve or the like.

Then, the stirring unit 130 is formed inside the casing 110 by the number of the additive inlet 120 serves to rapidly stir the additives added to the waste water flowing along the axial direction.

That is, the stirring unit 130 is provided inside the casing 110 so as to correspond one-to-one with the first tank 22, the second tank 24, and the third tank 26. It serves to stir the additives and waste water supplied from the.

At this time, since the stirring unit 130 is provided with a plurality of casing 110 inside the casing 110 at the same time to supply the additives of different components to the waste water flowing in the casing 110, and simultaneously stirring the purification of waste water by rapid stirring It can be performed in a short time.

In particular, the stirring unit 130 is preferably provided with a plurality of spaced intervals in the casing 110.

This is to allow sufficient stirring of the additives and waste water flowing at a constant speed in any one stirring unit 130.

Here, the stirring unit 130 includes an underwater motor 131, a shaft 132, an impeller 133, a partition member 134, a bracket 136, and a flow concentration guide member 137.

The underwater motor 131 is formed inside the casing 110 to be driven when an external power is applied, and the shaft 132 is rotated when the underwater motor 131 is driven.

At this time, the shaft 132 is formed to extend from the underwater motor 131 in the direction opposite to the flow direction of the waste water.

In addition, the impeller 133 is formed to rotate together with the shaft 132 and serves to stir the additive and the waste water introduced into each of the additive inlet 120.

In particular, the stirring unit 130 is provided to correspond to the tank (22, 24, 26), and is formed in one-to-one correspondence to the additive inlet (120).

In addition, each of the stirring unit 130 is a casing corresponding to the rear side of each of the additive inlet 120 in the advancing direction of the waste water so that the waste water and the additive can be stirred immediately after the additive is introduced into the corresponding additive inlet 120 ( 110 is preferably provided inside.

In addition, it is preferable that the total amount of waste water and additives is flow-induced in the direction of the impeller 133.

Thus, the casing 110 forms a partition member 134 therein, and the partition member 134 forms the flow channel 135 to open to both sides.

In other words, the partition member 134 serves to partition the inside of the casing 110 into a space having one additive inlet 120, and the partition member 134 has a flow channel at the same or similar height as that of the impeller 133. Through (135).

Therefore, additives and waste water introduced into each additive inlet 120 flow the entire amount to the impeller 133 through the corresponding flow channel 135. Accordingly, the stirring force of the additive and the waste water is maximized.

At this time, the partition member 134 is made of various shapes and various materials, may be formed integrally with the casing 110, it may be formed detachably.

On the other hand, the submersible motor 131 is preferably firmly fixed in the casing (110). This is to prevent malfunction due to rotation of the impeller 133 and vibration of the underwater motor 131.

Thus, the bracket 136 serves to support the submersible motor 131 with respect to the partition member 134.

That is, the bracket 136 connects one side to the partition member 134 and the other side to the circumferential surface of the underwater motor 131.

Of course, the bracket 136 is detachably connected to the partition member 134 and the underwater motor 131 by various methods such as bolting.

In addition, the bracket 136 may be modified in various shapes and various materials.

In addition, waste water and additives may be dispersed after passing through the flow channel 135 of the partition member 134.

Thus, the partition member 134 preferably forms the flow concentration guide member 137 to concentrate the waste water passing through the flow channel 135 to the impeller 133.

The flow concentration guiding member 137 is gradually narrower in cross section with respect to the flow direction of the waste water, thereby concentrating the waste water and additives to the impeller 133 as much as possible.

Of course, the flow concentration guiding member 137 is applicable to a variety of shapes and materials.

In addition, the flow concentration concentration member 137 may be formed integrally with the partition member 134 or may be detachably formed.

On the other hand, since the casing 110 is provided with the stirring unit 130, in particular, the submersible motor 131 and the impeller 133 as the number of the additive inlet 120, the maintenance of the stirring unit 130 is possible Preferably formed.

Thus, the casing 110 is preferably partitioned by the number of the stirring unit 130 is formed detachably.

That is, the casing 110 is divided into a plurality, it is preferably in contact with each other by the flange 116, it is preferable that the flange 116 in contact with each other is detachably coupled by a mechanical fastening element such as a bolt.

At this time, it is preferable that a corresponding stirring portion 130 is formed at each separated portion of the casing 110.

In addition, the casing 110 preferably passes through each of the stirring portions 130 to form an openable sampling port 140 for sampling the additives and the stirred waste water.

The sampling port 140 is formed to be opened and closed by a valve or the like to easily sample the purification of the waste water.

Of course, the sampling port 140 may be formed in various shapes, it is preferable that the sample is formed integrally on the circumferential surface of the casing (110).

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. I will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

1 is an installation diagram of a wastewater purification apparatus having a rapid stirrer according to an embodiment of the present invention.

2 is an internal view of a rapid stirrer according to an embodiment of the present invention.

Figure 3 is an enlarged view of the stirring portion of the rapid stirrer according to an embodiment of the present invention.

<Explanation of symbols on main parts of the drawings>

10: sludge storage tank 20: additive supply unit

22, 24, 26: 1,2,3 tank 30: filter

40: control unit 100: rapid stirrer

110: casing 120: additive inlet

130: stirring unit 131: submersible motor

132: shaft 133: impeller

134: partition member 135: flow channel

137: flow concentration guide member 140: sample collection port

Claims (5)

A casing having an inlet and an outlet to pass waste water therethrough; Additive inlet is provided with a plurality of opening and closing on the circumferential surface so as to be spaced along the axial direction of the casing, the additive inlet for introducing the additive for the purification of waste water; And And a stirring part which is formed inside the casing by the number of the additive inlet holes and rapidly agitates the additives added to the waste water flowing along the axial direction. The method of claim 1, wherein the stirring unit, An underwater motor formed inside the casing to drive when an external power source is applied; A shaft rotated when the underwater motor is driven; An impeller formed to rotate together with the shaft to stir additives and waste water introduced into each of the additive inlets; A partition member partitioning the inside of the casing into a space having one additive inlet and forming a flow channel for ensuring the flow of waste water; And And a bracket for detachably supporting the submersible motor with respect to the partition member. 3. The method of claim 2, The partition member is a rapid stirrer, characterized in that for forming a flow concentration concentrated member for concentrating the waste water passing through the flow channel to the impeller. The method according to any one of claims 1 to 3, The casing is partitioned by the number of the stirring portion is formed to be separated by a flange, a rapid stirrer, characterized in that for forming a sampling opening for sampling the waste water passing through each of the stirring portions. Sludge storage tank for storing waste water; A rapid stirrer for discharging the wastewater of the sludge storage tank to one side; A plurality of additive supply parts formed in the rapid stirrer for supplying wastewater purification additives of different components to different locations along the flow direction of the wastewater; A filter connected to the other side of the rapid stirrer to filter the suspended matter of the purified waste water; And And a control unit for controlling the operation for supplying the additives of each of the additive supply unit at the same time depending on whether or not to supply waste water from the sludge storage tank, The rapid stirrer, A casing for passing waste water through an inlet connected to the sludge storage tank and an outlet connected to the filter; An additive inlet which is formed to be opened and closed on a circumferential surface so as to be spaced along the axial direction of the casing, and is provided in one-to-one correspondence with each of the additive supply units, and the additive inlet is introduced to induce additives for purification of waste water; And And an agitator formed at the inside of the casing by the number of the additive inlets and rapidly stirring the additives added to the wastewater flowing along the axial direction.

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