KR102397619B1 - Wastewater treatment system with improved treating efficiency - Google Patents

Abstract

The present invention is a wastewater treatment apparatus comprising a primary pretreatment tank, a secondary pretreatment tank, a pretreatment tank having an adsorption space including a floating filter medium between the first and second pretreatment tanks, and a wastewater treatment tank,
The primary chorizo is an inlet, a first distribution panel installed at the rear of the inlet and having a first dispersion hole, and a nonwoven fabric installed at the rear of the first distribution panel and vertically mounted in multi-stage parallel to the first horizontal fixture. A first vertical multi-stage adsorption part, a first locking part having a first nonwoven fabric placed thereon, a second distribution panel installed on the first locking part and movably guided to the rear and having a second dispersion hole, the second dispersion A first non-woven fabric support including a non-woven fabric installed downward in a state integrally with the panel and spaced apart by a predetermined distance, the first elastic spring being interposed between the upper end of the first non-woven fabric support and the first stopper, compressed by wastewater and is configured to be compressed until the end of the first nonwoven support reaches the first stopper,
In the adsorption space, a floating filter medium is placed on the bottom surface, and the floating filter medium floats to the top by oxygen supplied through an oxygen supply nozzle mounted on the lower side, and the remaining particulate matter is adsorbed and removed,
The secondary pretreatment tank includes a second locking part having a second non-woven fabric placed on the top at the front end; A second vertical multi-stage consisting of a second non-woven fabric support mounted with a non-woven fabric installed downward in a state of being integrally spaced apart from the second non-woven fabric support, and a second vertical multi-stage non-woven fabric mounted vertically in multiple stages on a second horizontal fixture at the rear of the second non-woven fabric support. It comprises an adsorption unit, wherein the second elastic spring is interposed between the upper end of the second nonwoven support and the second stopper to be compressed by the wastewater until the end of the second nonwoven support reaches the second stopper. To provide a wastewater treatment device with improved treatment efficiency.

Description

Wastewater treatment system with improved treating efficiency

The present invention relates to a wastewater treatment device, and more particularly, it is possible to improve the treatment efficiency by first separating the sediment from the introduced wastewater, then removing the suspended matter by the supplied oxygen bubbles, and also effectively separating and discharging the scum. It relates to a wastewater treatment system with improved treatment efficiency.

There are 57 sewage treatment plants with anaerobic digesters installed in Korea. Most of the sewage treatment plants are medium-sized sewage treatment plants with a daily treatment capacity of 200,000 tons. It is known that the nitrogen load due to the extinguishing halfstream is about 86% of the designed nitrogen load, so separate countercurrent treatment is required for stable nitrogen removal.

Although the amount of countercurrent from the sewage treatment plant sludge treatment system is less than 1% of the influent flow, the nitrogen load is 15-40% of the inlet load, and in the case of phosphorus, it reaches 50%.

Accordingly, with the continuous promotion of energy self-reliance and sludge reduction projects, improvement, expansion, and new establishment of digesters for sewage treatment facilities are increasing. there is.

This high-concentration counter-effluent is returned to the inlet without additional treatment, causing rapid load fluctuations, making it difficult to operate the sewage treatment plant and worsening the quality of the effluent. It is known that the deterioration of water quality is particularly noticeable during the winter season when the water temperature is lowered.

Furthermore, it is expected that the load of food wastewater contaminants flowing into the sewage treatment facility will increase due to the discharge after solid-liquid separation according to the volume-rate food waste system, and the permission and expansion of the kitchen waste shredder. At this time, the effect of the nitrogen load by the countercurrent is aggravated and it is a big problem, but a system that can solve all the problems related to this in Korea has not been developed yet.

[Prior art literature]

[Patent Literature]

Domestic Patent Publication No. 10-2017-0009155 (2017.01.25)

Accordingly, the present invention has been devised to solve the above problems, and includes a primary pretreatment tank, a second pretreatment tank, and a pretreatment tank in which an adsorption space including a floating filter medium is formed between the first and second pretreatment tanks; An object of the present invention is to provide a wastewater treatment apparatus with improved treatment efficiency that can improve treatment efficiency as a wastewater treatment apparatus including a wastewater treatment tank.

The present invention for achieving the above object is a wastewater treatment comprising a first pretreatment tank, a second pretreatment tank, and a pretreatment tank and a wastewater treatment tank in which an adsorption space including a floating filter medium is formed between the first and second pretreatment tanks. As a device,

The primary pretreatment tank is an inlet, a first distribution panel installed at the rear of the inlet and having a first dispersion hole, and a nonwoven fabric installed at the rear of the first distribution panel and vertically mounted in multiple stages in parallel to a first horizontal holder. A first vertical multi-stage adsorption part, a first locking part having a first nonwoven fabric placed thereon, a second distribution panel installed on the first locking part and movably guided to the rear and provided with a second dispersion hole, the second dispersion A first non-woven fabric support including a non-woven fabric installed downward in a state integrally with the panel and spaced apart from each other by a predetermined interval, the first elastic spring being interposed between the upper end of the first non-woven fabric support and the first stopper, compressed by wastewater is configured to be compressed until the end of the first non-woven fabric support reaches the first stopper,

In the adsorption space, a floating filter medium is placed on the bottom, and the floating filter medium floats to the top by oxygen supplied through an oxygen supply nozzle mounted on the lower side, and the remaining particulate matter is adsorbed and removed,

The secondary pretreatment tank includes a second locking part having a second nonwoven fabric placed on the upper end at the front end; A second vertical multi-stage consisting of a second non-woven fabric support equipped with a non-woven fabric installed downward in a state of being integrally spaced apart from the second non-woven fabric support, and a second vertical multi-stage non-woven fabric mounted vertically in multiple stages on a second horizontal fixture at the rear of the second non-woven fabric support. It includes an adsorption unit, and is compressed by wastewater through a second elastic spring between the upper end of the second nonwoven support and the second stopper, until the end of the second nonwoven support reaches the second stopper.

The wastewater treatment tank according to the present invention has a body housing having a treatment space therein, an inflow space open vertically therein, an inner body housing provided in the inner central portion of the body housing, a lower end of the inner body housing and a body housing A diaphragm provided between the treatment space to divide the treatment space into a sedimentation space and a diffuser space, a wastewater inlet for supplying wastewater to the inlet space of the inner body housing, and a filtered treated water provided at the upper end of the body housing to drain A treated water discharge unit to become a sediment discharge unit for discharging the sediment deposited in the settling space of the body housing, which is a lower side of the inner body housing; A treated water supply unit for dispensing oxygen bubbles into the aeration space, an oxygen supply rotating unit for rotating the treated water supply unit based on the inner body housing, and a scum provided to float in the treated water of the aeration space A scum discharge unit for separating and discharging, and a wastewater circulation unit for separating the wastewater contained in the sediment discharged through the sediment discharge unit and circulating it to the treatment space of the body housing; After the wastewater flows into the sedimentation space along the inlet space of the inner body housing and the sediment is precipitated, the wastewater is moved to the aeration space by the treated water supply part, and then mixed with the oxygen bubbles supplied by the oxygen supply part to form suspended solids. The separated, treated water from which the suspended matter is removed is discharged to the treated water discharge unit, and the scum is separated and discharged by the scum discharge unit.

Preferably, the inner body housing further includes a diffusion portion inclined outwardly toward the lower end toward the lower side.

And the treated water discharge part has a treated water discharge space part open upwardly therein, a treated water discharge pipe provided along the outer periphery of the upper end of the body housing, and a plurality of the treated water discharge pipe at regular intervals. and a treated water discharge pipe for discharging the treated water introduced into the treated water discharge space, wherein the treated water from the aeration space overflows and moves into the treated water discharge space, and then is discharged through each treated water discharge pipe.

In addition, a plurality of discharge diaphragms are further provided to partition the treated water discharge space of the treated water discharge pipe to a predetermined size, and each of the treated water discharge spaces is provided with the treated water discharge pipe, respectively.

And it further includes a discharge space adjusting unit for adjusting the size of each divided treated water discharge space by moving the discharge diaphragm along the treated water discharge pipe.

In addition, the discharge space control unit has a predetermined width, and a diaphragm frame provided along the corresponding end of the discharge diaphragm in contact with the inner surface of the treated water discharge space unit, a diaphragm provided between the diaphragm frame and the treated water discharge pipe Packing, a moving plate extending from the diaphragm frame and having a predetermined arc in an outer circumferential direction, a driven gear portion formed along an outer circumferential surface of the moving plate, a driving gear meshing with the driven gear portion, and rotating the driving gear a drive motor for

And the bottom surface of the body housing is formed to be inclined downward toward the outside with respect to the central point, and the sediment discharge part is a sediment discharge pipe formed along the outer periphery of the bottom surface of the body housing, and deposits by scraping the bottom surface of the body housing It includes a scraper for moving the deposited sediment to the sediment discharge pipe, a scraper driving part for rotating the scraper based on the center point of the bottom surface of the body housing, and a sediment discharge pipe for discharging the sediment deposited in the sediment discharge pipe .

In addition, the wastewater circulation unit has a dewatering space therein, a dewatering housing provided in the sediment discharge pipe, a dewatering screw rotatably provided in the dewatering housing, a dewatering motor for rotating the dewatering screw, and dewatering in the dewatering housing It includes a solid discharge unit for discharging the deposited solids, and a circulation supply unit for supplying the wastewater dewatered in the dewatering housing to the treatment space of the body housing.

The circulation supply unit may include a circulation supply pipe for supplying dewatered wastewater by connecting the dewatering housing and the body housing, a circulation supply tank communicating with the circulation supply pipe to store the dehydrated wastewater, and wastewater stored in the circulation supply tank a second circulation supply pipe for introducing into the circulation supply pipe, and the circulation supply pipe and the second circulation supply pipe are respectively opened and closed, and the supplied wastewater is supplied to the body housing along the circulation supply pipe or supplied to the circulation supply tank to provide a second circulation later and a circulation supply valve for supplying the wastewater stored through the supply pipe to the body housing.

In addition, it further includes a first sensor for measuring the amount of wastewater flowing into the treatment space of the body housing, and a circulation control unit for receiving the signal of the first sensor to control the circulation supply valve.

In addition, the treated water supply unit includes a plurality of treated water supply pipes provided along the outer periphery of the body housing so that a lower end communicates with the settling space and an upper end communicates with the diffuser space, and each treated water supply pipe to open and close It includes a treated water supply valve for

In addition, the oxygen supply unit has an oxygen supply space portion between the diaphragm and an oxygen supply plate provided outside the lower end of the inner body housing, a plurality of oxygen injection nozzles formed at regular intervals along the oxygen supply plate, and and an oxygen supply pump for supplying oxygen to the oxygen supply space of the oxygen supply plate.

And the oxygen supply plate is formed to be inclined downward from the inner end adjacent to the inner body housing toward the outer end.

In addition, the oxygen supply rotating unit, a rotating frame positioned in the inlet space of the inner body housing to be connected to the oxygen supply plate, a rotating driving unit for rotating the rotating frame, and fixing the rotating driving unit to the inner body housing Includes a fixed frame for

And the scum discharge unit has a scum frame and a scum discharge port, is provided in the scum frame and includes a scum discharge head for discharging the scum, a scum buoy for levitating the scum frame, and one end of the scum discharge port with a flexible material It communicates, and the other end includes a scum discharge tube positioned outside the body housing to discharge scum, and a scum discharge pump that generates a suction force to discharge the scum through the scum discharge port and the scum discharge tube.

In addition, a delay unit, which is located in the aeration space, and delays the upward movement of oxygen bubbles and wastewater from which the sediment is removed, is further included to improve the mixing rate.

And the delay unit, the outer end is provided along the inner surface of the body housing, the inner end is inclined downward toward the inner side, the inner end is spaced apart from the outer peripheral surface of the inner body housing a first delay plate to form a movement path, and a second delay plate having an inner end provided along the outer surface of the inner body housing and inclined downward toward the outside, the outer end being spaced apart from the inner circumferential surface of the body housing at a predetermined distance to form a movement path, At least one of the first and second delay plates is provided, respectively, and is alternately positioned in the vertical direction.

In addition, the first delay plate and the second delay plate, a plurality of communication holes are further formed.

And it further includes a gas discharge unit for discharging the gas contained in the wastewater.

In addition, the gas discharge part, the gas discharge housing extending upwardly of the body housing, which is formed narrower toward the upper side, is provided inside the gas discharge housing so as to extend upward of the inner body housing, and is narrower toward the upper side a first gas-liquid filter provided between the gas discharge housing and the internal gas discharge housing to separate gas and liquid, a first dry filter for filtering the gas that has passed through the first gas-liquid filter; It includes a second gas-liquid filter provided in the internal gas discharge housing to separate gas and liquid, and a second dry filter for filtering the gas that has passed through the second gas-liquid filter.

A circulation unit for circulating the treated water of the aeration space to the inlet space is further provided in the inner body housing.

In addition, the circulation unit has a plurality of circulation holes formed along the inner body housing, a communication hole corresponding to each circulation hole, a circulation ring provided to surround the inner body housing, and rotate the circulation ring and a circulation opening/closing driving unit for controlling the opening and closing degree of each communication hole and the corresponding circulation hole.

And the circulation part, a plurality of circulation holes formed along the inner body housing, a circulation opening and closing ring provided to surround the inner body housing, movably provided along the inner body housing, and the circulation opening and closing ring to the inner body and a circulation opening/closing driving unit for controlling the opening/closing degree of the circulation hole by moving it along the housing.

As described above, according to the wastewater treatment apparatus according to the present invention, after separating the sediment from the introduced wastewater, the suspended matter is also removed by the supplied oxygen, as well as the generated scum, and the gas can be treated. It is a very useful and effective invention that makes it possible to improve the efficiency.

1 is a view showing the configuration of a pretreatment tank according to the present invention;
2 is a view showing a wastewater treatment apparatus according to the present invention;
3 is a view showing a treated water discharge unit according to the present invention;
4 is a view showing a sediment discharge unit according to the present invention;
5 is a view showing a wastewater circulation unit according to the present invention;
6 is a view showing an oxygen supply unit according to the present invention;
7 is a view showing a scum discharge unit according to the present invention
8 is a view showing a gas discharge unit according to the present invention;
9 is a view showing a state in which the circulation unit according to the present invention is further provided
10 is a view showing another embodiment of the circulation unit according to the present invention

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION The detailed description set forth below in conjunction with the appended drawings is intended to describe exemplary embodiments of the present invention and is not intended to represent the only embodiments in which the present invention may be practiced. The following detailed description includes specific details in order to provide a thorough understanding of the present invention. However, one of ordinary skill in the art to which the present invention pertains will recognize that the present invention may be practiced without these specific details.

In some cases, well-known structures and devices may be omitted or shown in block diagram form focusing on core functions of each structure and device in order to avoid obscuring the concept of the present invention.

Throughout the specification, when a part is said to "comprising or including" a certain component, it does not exclude other components unless otherwise stated, meaning that other components may be further included. do. In addition, the term “…unit” described in the specification means a unit that processes at least one function or operation. Also, "a or an", "one", "the" and like related terms are used differently herein in the context of describing the invention (especially in the context of the following claims). Unless indicated or clearly contradicted by context, it may be used in a sense including both the singular and the plural.

In describing the embodiments of the present invention, if it is determined that a detailed description of a well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout this specification.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view showing the configuration of a pretreatment tank according to the present invention, FIG. 2 is a view showing a wastewater treatment apparatus according to the present invention, FIG. 3 is a view showing a treated water discharge unit according to the present invention, FIG. 4 is a view showing a sediment discharge unit according to the present invention, FIG. 5 is a view showing an oxygen supply unit according to the present invention, FIG. 6 is a view showing a scum discharge unit according to the present invention, and FIG. 7 is a view showing a scum discharge unit according to the present invention It is a view showing a gas discharge unit, FIG. 8 is a view showing a state in which the circulation unit according to the present invention is further provided, and FIG. 9 is a view showing another embodiment of the circulation unit according to the present invention.

1 is a block diagram of a pretreatment tank in which the present invention is implemented. The pretreatment tank is formed by connecting the first pretreatment tank (L) and the second pretreatment tank (R) in a series structure, but wastewater flows in through the inlet 11 The first distribution panel 14 having a plurality of distribution holes 13 formed therein is installed individually or in plurality.

In the primary pretreatment tank (L), the flow of wastewater is evenly distributed up, down, left and right by the first distribution panel (14), and delivered to the subsequent first vertical multi-stage adsorption unit (15). The first vertical multi-stage adsorption unit 15 is made of a nonwoven fabric 16 that is vertically mounted in multiple stages in parallel to the first horizontal holder 17 . Each of the nonwoven fabrics may move inside according to the flow of the water flow, and is preferably fixedly installed by the first vertical holder 18 .

The first vertical multi-stage adsorption unit 15 adsorbs various suspended substances or solids in wastewater and primarily removes them. At this time, the sludge is settling by gravity and discharged downward.

Since the wastewater introduced through the inlet 11 passes through the plurality of dispersion holes 13 while colliding with the first distribution panel 14, the wastewater flows evenly up and down, left and right, and colliding with the distribution panel 4, the plurality of distribution holes By the process passing through (13), a large amount of fine air bubbles are generated inside the primary pretreatment tank (L).

And, foreign substances from the wastewater introduced into the primary pretreatment tank (L) are floated or precipitated due to the specific gravity difference. As it floats upward, separation and removal by the first vertical multi-stage adsorption unit 15 is facilitated.

Here, since the primary pretreatment tank (L) uses the buoyancy of air, it can be said that the sedimentation rate of the sludge is very slow, but it is possible to remove the floating foreign substances in a faster time.

And even in the primary pretreatment tank (L) using the buoyancy of air, foreign substances having a large specific gravity are precipitated and collected in a funnel-shaped sludge collecting part provided at the bottom, and the precipitated foreign substances are transferred to the outside by a transfer screw (not shown). is emitted

A second distribution panel 20 is additionally installed at the end of the primary pretreatment tank L in the direction in which the wastewater proceeds. The second dispersion panel 20 is installed on the line of the first locking part (B), and the first pretreatment tank (L) and the adsorption space part (C) to be described later are installed on the first locking part (B) of the second dispersion panel (B). They are isolated from each other by panels 20 .

Foreign substances of a size that cannot pass through the second dispersion hole 21 of the second dispersion panel 20 are removed by floating or sedimentation in the primary pretreatment tank L, and the second dispersion of the second dispersion panel 20 is removed. Only small-sized floating matter or sedimentary substances passing through the ball 21 are introduced into the adsorption space C together with the wastewater.

In the present invention, the upper end of the second distribution panel 20 installed on the first locking part B is guided movably to the rear, and then the first non-woven fabric support 22 on which the non-woven fabric is mounted is attached to the second It is installed downward in a state spaced apart from the distribution panel 20 integrally with a predetermined interval. In addition, while the first elastic spring 25 is interposed between the upper end of the first nonwoven support 22 and the first stopper 23 and compressed by wastewater, the end of the first nonwoven support 22 is connected to the first stopper ( 23) until it is compressed.

The first non-woven fabric support 22 is made of a material such as plastic and is composed of a frame having a square shape, and may be of a form in which a nonwoven fabric is fixed and mounted inside the frame, but is not necessarily limited thereto.

Particulate matter contained in the wastewater that has passed through the second dispersion hole 21 of the second dispersion panel 20 is filtered by the nonwoven fabric mounted on the first non-woven fabric support 22 installed at the rear end, and the supernatant liquid is formed downward through the adsorption space (C).

At the same time, the lower end of the second distribution panel 20 blocks the water passage while pressing the first nonwoven fabric 24 fixedly supported in a V shape on the upper end of the first locking part B by water pressure. Accordingly, particulate matter suspended in the wastewater may be filtered by the first nonwoven fabric 24 , and only the supernatant may flow through the nonwoven fabric and flow into the adsorption space C .

According to this configuration, even if a large amount of wastewater with a large content of particulate matter flows into the first pretreatment tank L at once, the second dispersion hole 21 and the first locking part B of the second dispersion panel 20 are ), only through the first nonwoven fabric 24 installed in the water flow is formed, so that only a constant flow rate of wastewater in a state in which a significant amount of particulate matter has been removed is sent to the adsorption space (C).

In the adsorption space (C), a floating filter medium 30 (for example, polyurethane material) is mounted on the bottom surface, and the floating filter medium floats to the top by oxygen supplied through the oxygen supply nozzle 26 mounted on the lower side and remains remove particulate matter. The oxygen supply nozzle 26 is connected to an oxygen supply pump 730, which will be described later, to supply oxygen.

A third distribution panel 20 ′ is additionally installed at the rear end of the adsorption space C in the direction in which the wastewater proceeds. The third distribution panel 20' is installed on the line of the second stopping part B', and the adsorption space part C and the secondary pretreatment tank R to be described later are installed on the second stopping part B'. They are isolated from each other by the third distribution panel 20'.

The fine-sized suspended matter passing through the third distribution hole 21' of the third distribution panel 20' is introduced into the secondary pretreatment tank R together with the wastewater.

In the present invention, the upper end of the third distribution panel 20' installed on the second locking part B' is guided to be movable rearwardly, and then the second non-woven fabric support 22' to which the nonwoven fabric is mounted. is integrally installed with the third distribution panel 20 ′ and spaced apart from each other by a predetermined distance. In addition, the end of the second nonwoven support 22' is compressed by wastewater through the second elastic spring 25' interposed between the upper end of the second nonwoven support 22' and the second stopper 23'. It is compressed until it reaches the second stopper 23'.

The second non-woven fabric support 22 ′ is similarly made of a material such as plastic and configured as a frame having a square shape, and may be of a type fixed and mounted on the inside of the frame, but is not necessarily limited thereto.

The fine particulate matter contained in the wastewater that has passed through the third dispersion hole 21' of the third dispersion panel 20' is filtered by the nonwoven fabric mounted on the second nonwoven fabric support 22' installed at the rear end, and the supernatant is It flows into the secondary pretreatment tank (R) through the waterway formed below.

At the same time, the third distribution panel 20 ′ blocks the water channel while pressing the second nonwoven fabric 24 ′ fixed and supported in a V shape to the upper end of the second locking part B ′ at the lower end of the third distribution panel 20 ′ by water pressure. . Accordingly, the fine particulate matter in the wastewater is filtered by the second nonwoven fabric 24 ′, and only the supernatant flows through the nonwoven fabric so that it can be introduced into the secondary pretreatment tank R.

In the secondary pretreatment tank (R), a second vertical multi-stage adsorption unit (15') is mounted therein. The second vertical multi-stage adsorption unit 15 ′ is made of a nonwoven fabric 16 ′ vertically mounted in multiple stages in parallel to the second horizontal holder 17 ′. Each of the nonwoven fabrics may move inside according to the flow of the water flow, and is preferably fixedly installed by the second vertical holder 18'.

The second vertical multi-stage adsorption unit 15 ′ adsorbs fine suspended solids or solids that may be present in wastewater and additionally removes them. At this time, the excess sludge is settling by gravity and discharged downward.

A fourth distribution panel 13' having a fourth distribution hole 14' is additionally installed at the end of the secondary pretreatment tank R in the direction in which the wastewater proceeds.

Through the above configuration, the wastewater flows into the wastewater inlet 400 of the wastewater treatment apparatus of the present invention in a state in which a considerable amount of suspended substances, which are various pollutants, have been pretreated, thereby greatly reducing the load in the subsequent procedure.

As shown in the drawing, the wastewater treatment apparatus according to the present invention has a body housing 100, an inner body housing 200, a diaphragm 300, a wastewater inlet 400, a treated water outlet 500, and a sediment discharge. It includes a unit 600 , an oxygen supply unit 700 , a scum discharge unit 800 , a treated water supply unit 1000 , an oxygen supply rotation unit 1100 , and a wastewater circulation unit 1200 .

The body housing 100 has a processing space portion 110 formed therein, and is formed in a circular cylinder or square and polygonal shape having a diameter.

And, the inner body housing 200 has an inlet space 202 opened in the vertical direction therein, is provided in the inner central portion of the body housing 100, and is preferably formed in a cylindrical shape.

The diaphragm 300 has a plurality of through-holes 310 and is provided between the lower end of the inner body housing 200 and the body housing 100 to form the treatment space 110 with the settling space 112 and the diffuser space ( 114).

Here, the inner body housing 200 further includes a diffusion part 210 that is inclined outward toward the lower end as it goes downward, and diffuses while reducing the speed of wastewater flowing into the sedimentation space part 112 to increase the sedimentation rate of the sediment. .

In addition, the wastewater inlet 400 is provided to supply wastewater to the inlet space 210 of the inner body housing 200 .

The treated water discharge unit 500 is provided at the upper end of the body housing 100 to drain the filtered treated water.

And the sediment discharge unit 600 is provided to discharge the sediment deposited in the settling space portion 112 of the body housing 100, which is the lower side of the inner body housing 200 .

The treated water supply unit 1000 is provided to introduce the treated water from which the sediment is separated in the sedimentation space unit 112 into the aeration space unit 114 .

Also, the oxygen supply unit 700 is provided on the upper side of the diaphragm 300 to inject oxygen bubbles into the air diffuser space unit 114 .

The scum discharge unit 800 is provided to float in the treated water of the aeration space unit 114 to separate and discharge the scum.

Looking at the operating state of the wastewater treatment apparatus as described above, after the wastewater is supplied to the inlet space 210 of the inner body housing 200 by the wastewater inlet 400 , it flows into the sedimentation space 112 and deposits It is precipitated.

Then, the wastewater from which the sediment is separated is moved to the aeration space 114 by the treated water supply unit 1000 , and then mixed with the oxygen bubbles supplied by the oxygen supply unit 700 to separate the suspended matter.

The treated water from which the floating matter is removed is discharged to the treated water discharge unit 500 , and the scum is separated and discharged by the scum discharge unit 800 .

Accordingly, it is possible to effectively remove sediment, suspended matter, and scum from wastewater, thereby improving treatment efficiency.

In addition, the oxygen supply rotating unit 1100 is provided to rotate the treated water supply unit 1000 based on the inner body housing 200 .

The wastewater circulation unit 1200 is provided to separate the wastewater contained in the sediment discharged through the sediment discharge unit 600 and circulate it to the treatment space unit 110 of the body housing 100 .

For this purpose, the treated water discharge unit 500 includes a treated water discharge pipe 510 and a treated water discharge pipe 520 as shown in FIG. 3 .

The treated water discharge pipe 510 has a treated water discharge space 512 that is opened upwardly therein, and is provided along the outer periphery of the upper end of the body housing 100 .

In addition, a plurality of treated water discharge pipes 520 are provided in the treated water discharge pipe path 510 at regular intervals to discharge the treated water introduced into the treated water discharge space 512 .

After the treated water in the aeration space 114 overflows into the treated water discharge space 512 and moves, it is drained through each treated water discharge pipe 520 .

Accordingly, the treated water is discharged in a plurality of directions to improve the discharge efficiency.

Here, a plurality of discharge diaphragms 530 are further provided to partition the treated water discharge space 512 of the treated water discharge pipe 510 to a predetermined size.

Each treated water discharge space 512 partitioned by the discharge diaphragm 530 is provided with a treated water discharge pipe 520 to quickly discharge the treated water from the corresponding treated water discharge space 512 .

And the treated water discharge unit 500 moves the discharge diaphragm 530 along the treated water discharge pipe 510 to adjust the size of each treated water discharge space 512 divided by the discharge space adjusting unit 540. further includes

The discharge space control unit 540 includes a diaphragm frame 541 , a diaphragm packing 542 , a moving plate 543 , a driven gear unit 544 , a driving gear 545 , and a driving motor 546 .

The diaphragm border 541 has a predetermined width and is provided along the corresponding end of the discharge diaphragm 530 in contact with the inner surface of the treated water discharge space 512 .

In addition, the diaphragm packing 542 is provided between the diaphragm border 541 and the treated water discharge pipe 510 to mutually partition each treated water discharge space 512 .

The moving plate 543 is formed extending from the diaphragm edge 541 , is formed in a predetermined arc in the outer circumferential direction, and is formed to be movable along the outer periphery of the treated water discharge pipe 510 .

And the driven gear unit 544 is formed along the outer peripheral surface of the moving plate (543).

The driving gear 545 is meshed with the driven gear unit 544 , and the driving motor 546 is provided to rotate the driving gear 545 .

In addition, as shown in FIG. 4, the bottom surface of the body housing 100 is formed to be inclined downward toward the outside with respect to the central point.

And the sediment discharge unit 600 is composed of a sediment discharge pipe line 610 , a scraper 620 , a scraper driving unit 630 , and a sediment discharge pipe 640 .

The sediment discharge pipe 610 is formed along the outer periphery of the bottom surface of the body housing 100 .

In addition, the scraper 620 is provided to move the sediment deposited by scraping the bottom surface of the body housing 100 to the sediment discharge pipe 610 .

The scraper driving unit 630 is provided to rotate the scraper 620 based on the center point of the bottom surface of the body housing 100 .

And the sediment discharge pipe 640 is provided to discharge the sediment deposited in the sediment discharge pipe path (610).

5, the wastewater circulation unit 1200 includes a dewatering housing 1210, a dewatering screw 1220, a dewatering motor 1230, a solid discharge unit 1240, and a circulation supply unit 1250.

The dewatering housing 1210 has a dewatering space 1212 therein, and is provided in the sediment discharge pipe 640 .

And the dewatering screw 1220 is rotatably provided in the dewatering housing 1210 .

The dewatering motor 1230 is provided to rotate the dewatering screw 1220 .

In addition, the solids discharge unit 1240 is provided to discharge the precipitated solids dehydrated in the dewatering housing 1210.

The circulation supply unit 1250 is provided to supply the wastewater dewatered in the dewatering housing 1210 to the treatment space 110 of the body housing 100 .

According to the wastewater circulation unit 1200, as wastewater contained in the discharged sediment is recovered and circulated back to the body housing 100, the treatment efficiency in the body housing 100 can be improved as well as the discharge It also facilitates the subsequent treatment of the precipitated solids.

Here, the circulation supply unit 1250 includes a circulation supply pipe 1252 , a circulation supply tank 1254 , a second circulation supply pipe 1256 , and a circulation supply valve 1258 .

The circulation supply pipe 1252 is provided to supply the dewatered wastewater by connecting the dewatering housing 1210 and the body housing 100 .

And the circulation supply tank 1254 is provided in communication with the circulation supply pipe 1252 to store the dehydrated wastewater.

The second circulation supply pipe 1256 is provided to introduce the wastewater stored in the circulation supply tank 1254 into the circulation supply pipe 1254 .

In addition, the circulation supply valve 1258 opens and closes the circulation supply pipe 1252 and the second circulation supply pipe 1256, respectively, and supplies the supplied wastewater to the body housing 100 along the circulation supply pipe 1252 or the circulation supply tank 1254. ) to supply the wastewater stored later through the second circulation supply pipe 1256 to the body housing 100 .

In addition, the wastewater circulation unit 1200 further includes a first sensor 1260 and a circulation control unit 1270 .

The first sensor 1260 is provided to measure the amount of wastewater flowing into the treatment space 110 of the body housing 100 .

In addition, the circulation control unit 1270 is provided to receive the signal of the first sensor 1260 to control the circulation supply valve 1258 provided in the circulation supply pipe 1252 and the second circulation supply pipe 1256, respectively.

The circulation control unit 1270 prevents excessive supply of wastewater to the body housing 100, and stores the dehydrated wastewater in the circulation supply tank 1254 to automatically adjust the supply amount.

Also, as shown in FIG. 6 , the treated water supply unit 1000 includes a treated water supply pipe 1010 and a treated water supply valve 1020 .

A plurality of treated water supply pipes 1010 are provided along the outer periphery of the body housing 100 so that the lower end communicates with the sedimentation space 112 and the upper end communicates with the aeration space 114 .

And the treated water supply valve 1020 is provided to open and close each treated water supply pipe 1010 .

The wastewater from the sedimentation space 112 may be supplied to the aeration space 114 through each of these treated water supply pipes 1010 .

Of course, by operating each treated water supply valve 1020 to open and close the corresponding treated water supply pipe 1010, the amount of wastewater supplied can be adjusted.

Also, the oxygen supply unit 700 includes an oxygen supply plate 710 , an oxygen injection nozzle 720 , and an oxygen supply pump 730 .

The oxygen supply plate 710 has an oxygen supply space 712 therein, and is provided outside the lower end of the inner body housing 200 .

In addition, a plurality of oxygen injection nozzles 720 are formed at regular intervals along the oxygen supply pipe 710 , and the oxygen supply pump 730 supplies oxygen to the oxygen supply space 712 of the oxygen supply plate 710 . provided

Here, the oxygen supply plate 710 is inclined downward from the inner end adjacent to the inner body housing 200 toward the outer end.

Oxygen bubbles are jetted upward and outward by the plurality of oxygen injection nozzles 720 provided on the oxygen supply plate 710 , thereby improving the mixing rate with the treated water.

In addition, the oxygen supply rotating unit 1100 includes a rotating frame 1110 , a rotating driving unit 1120 , and a fixed frame 1130 .

The rotating frame 1110 is located in the inlet space 202 of the inner body housing 200 so as to be connected to the oxygen supply plate 710 .

The rotation frame 1110 is branched outward in a plurality with respect to the center to form an end.

Of course, it is natural that the lower end of the inner body housing 200 is installed so that the end of the rotating frame 1110 is connected to the oxygen supply plate 710 so that a rotatably cutout (not shown) is formed.

In addition, the rotation driving unit 1120 is provided to rotate the rotation frame 1110 , and the fixed frame 1130 is provided to fix the rotation driving unit 1120 to the inner body housing 200 .

The fixed frame 1130 also has a plurality of branches to the outside with respect to the center, so it is natural that the introduced wastewater may be moved to the lower side.

In addition, as shown in Figure 7, the scum discharge unit 800 is composed of a scum frame 810, a scum discharge head 820, a scum buoy 830, a scum discharge tube 840 and a scum discharge pump 850. do.

The scum discharge head 820 has a scum discharge port 822 and is provided in the scum frame 810 to discharge the scum.

And the scum buoy 830 is provided to levitate the scum frame 810, and a plurality of scum buoys are preferably provided.

The scum discharge tube 840 is made of a flexible material, and one end communicates with the scum discharge port 822 of the scum discharge head 820, and the other end is located outside the body housing 100 to discharge the scum.

In addition, the scum discharge pump 850 generates a suction force to discharge the scum through the scum discharge port 822 and the scum discharge tube 840 .

Here, a head lifting unit 860 for elevating the scum discharge head 820 is further provided in the scum frame 810 .

By moving the scum discharge head 820 by the head lifting unit 860 to adjust the position of the scum discharge port 822, the discharge amount can be adjusted in response to the height of the generated scum.

In addition, the body housing 100 further includes a delay unit 120 positioned in the aeration space 114 to delay the upward movement of the wastewater from which the sediment has been removed and oxygen bubbles to improve the mixing rate.

The delay unit 120 includes a first delay plate 122 and a second delay plate 124 .

The first delay plate 122 has an outer end provided along the inner surface of the body housing 100, and is inclined downward toward the inner side, and the inner end is spaced apart from the outer circumferential surface of the inner body housing 200 by a predetermined distance to form a movement path. to form

In addition, the second delay plate 124 has an inner end provided along the outer surface of the inner body housing 200, and is inclined downward toward the outer side, and the outer end is spaced apart from the inner circumferential surface of the body housing 100 by a predetermined distance. to form

At least one of these first delay plates 122 and second delay plates 124 is provided, and they are alternately positioned in the vertical direction to improve the mixing rate of oxygen bubbles and wastewater from which sediment has been removed to separate suspended matter. .

In addition, a plurality of communication holes 126 are further formed in the first retardation plate 122 and the second retardation plate 124 so that some of the wastewater and oxygen bubbles pass therethrough.

In addition, as shown in Figure 8, it further includes a gas discharge unit 900 for discharging the gas contained in the wastewater.

The gas discharge unit 900 includes a gas discharge housing 910, an internal gas discharge housing 920, a first gas-liquid filter 930, a first dry filter 940, a second gas-liquid filter 950, and a second dry type. It consists of a filter 960 .

The gas discharge housing 910 extends upwardly of the body housing 100, and is formed narrower toward the upper side.

And the internal gas exhaust housing 920 is provided inside the gas exhaust housing 910 so as to extend upwards of the internal body housing 200, and is formed narrower toward the upper side.

The first gas-liquid filter 930 is provided between the gas discharge housing 910 and the internal gas discharge housing 920 to separate gas and liquid.

In addition, the first dry filter 940 filters the gas that has passed through the first gas-liquid filter 930 .

The second gas-liquid filter 950 is provided in the internal gas discharge housing 920 to separate gas and liquid.

And the second dry filter 960 filters the gas that has passed through the second gas-liquid filter 950 .

As the wastewater introduced by the gas discharge unit 900 and the gas contained in the treated water are treated, toxic substances and odors contained in the gas can be treated.

Also, as shown in FIG. 9 , a circulation unit 220 for circulating the treated water from the aeration space 114 to the inlet space 210 is further provided in the inner body housing 200 .

The circulation unit 220 is composed of a circulation hole 222 , a circulation ring 224 , and a circulation opening/closing driving unit 226 .

A plurality of circulation holes 222 are formed along the inner body housing 200 .

And the circulation ring 224 has a communication hole 225 corresponding to each circulation hole 222 and is provided to surround the inner body housing 200 .

The circulation opening/closing driving unit 226 rotates the circulation ring 224 to adjust the degree of opening and closing of each communication hole 225 and the corresponding circulation hole 222 to adjust the amount of circulation.

On the other hand, as shown in FIG. 10, the circulation unit 220' of another embodiment is composed of a circulation hole 222', a circulation opening/closing ring 224', and a circulation opening/closing driving unit 226'.

A plurality of circulation holes 222 ′ are formed along the inner body housing 200 .

And the circulation opening/closing ring 224 ′ is provided to surround the inner body housing 200 , and is provided to be movable along the inner body housing 200 .

The circulation opening/closing driving unit 226' moves the circulation opening/closing ring 224' to adjust the degree of opening and closing of the circulation hole 222' to adjust the amount of circulation.

100: body housing
200: inner body housing
300: multi-attack plate
400: wastewater inlet
500: treated water discharge unit
600: sediment discharge part
700: oxygen supply unit
800: scum discharge unit
900: gas exhaust unit
1000: treated water supply unit
1100: oxygen supply rotating part

Claims (1)

A wastewater treatment apparatus comprising a primary pretreatment tank, a secondary pretreatment tank, and a pretreatment tank and a wastewater treatment tank in which an adsorption space including a floating filter is formed between the first and second pretreatment tanks,
The primary pretreatment tank is an inlet, a first distribution panel installed at the rear of the inlet and having a first dispersion hole, and a nonwoven fabric installed at the rear of the first distribution panel and vertically mounted in multi-stage parallel to a first horizontal holder. A first vertical multi-stage adsorption part, a first locking part having a first nonwoven fabric placed thereon, a second distribution panel installed on the first locking part and movably guided to the rear and having a second dispersion hole, the second dispersion A first non-woven fabric support including a non-woven fabric installed downward in a state integrally with the panel and spaced apart by a predetermined distance, the first elastic spring being interposed between the upper end of the first non-woven fabric support and the first stopper, compressed by wastewater and is configured to be compressed until the end of the first nonwoven support reaches the first stopper,
In the adsorption space, a floating filter medium is placed on the bottom surface, and the floating filter medium floats to the top by oxygen supplied through an oxygen supply nozzle mounted on the lower side, and the remaining particulate matter is adsorbed and removed,
The secondary pretreatment tank includes a second locking part having a second non-woven fabric placed on the top at the front end; A second vertical multi-stage consisting of a second non-woven fabric support mounted with a non-woven fabric installed downward in a state of being integrally spaced apart from the second non-woven fabric support, and a second vertical multi-stage non-woven fabric mounted vertically in multiple stages on a second horizontal fixture at the rear of the second non-woven fabric support. Comprising an adsorption unit, the second elastic spring is interposed between the upper end of the second nonwoven support and the second stopper to be compressed by the wastewater until the end of the second nonwoven support reaches the second stopper,
The wastewater treatment tank,
Body housing having a processing space therein;
an inner body housing having an inflow space part open vertically therein, and provided in an inner central portion of the body housing;
a diaphragm provided between the lower end of the inner body housing and the body housing to partition the processing space into a settling space and an aeration space;
a wastewater inlet for supplying wastewater to the inlet space of the inner body housing;
a treated water discharge unit provided at the upper end of the body housing to drain the filtered treated water;
a sediment discharge unit for discharging the sediment deposited in the settling space of the body housing, which is a lower side of the inner body housing;
a treated water supply unit for introducing the treated water from which the sediment is separated in the precipitation space unit into the aeration space unit;
an oxygen supply unit for injecting oxygen bubbles into the aeration space;
an oxygen supply rotating unit for rotating the treated water supply unit based on the inner body housing;
a scum discharge unit provided to float in the treated water of the aeration space unit to separate and discharge the scum; and
and a wastewater circulation part for separating the wastewater contained in the sediment discharged through the sediment discharge part and circulating it to the treatment space part of the body housing;
The wastewater supplied by the wastewater inlet is
After the sediment flows into the settling space along the inlet space of the inner body housing and the sediment is precipitated, it is moved to the aeration space by the treated water supply unit, and then mixed with the oxygen bubbles supplied by the oxygen supply unit to separate the suspended matter,
The treated water from which the floating matter is removed is discharged to the treated water discharge unit, and the scum is separated and discharged by the scum discharge unit,
The treated water discharge unit,
It has a treated water discharge space part open upward therein, a treated water discharge pipe provided along the outer periphery of the upper end of the body housing, and a plurality of treated water discharge pipes provided at regular intervals in the treated water discharge space. and a treated water discharge pipe for discharging the treated water, wherein the treated water of the aeration space overflows and moves into the treated water discharge space, and then is drained through each treated water discharge pipe,
A plurality of discharge diaphragms are provided to partition the treated water discharge space of the treated water discharge pipe to a predetermined size, and each of the treated water discharge spaces is provided with the treated water discharge pipe,
and a discharge space adjusting unit for adjusting the size of each divided treated water discharge space by moving the discharge diaphragm along the treated water discharge pipe,
The discharge space control unit has a certain width, and a diaphragm frame provided along the corresponding end of the discharge diaphragm in contact with the inner surface of the treated water discharge space unit, a diaphragm packing provided between the diaphragm frame and the treated water discharge pipe, the A moving plate extending from the diaphragm frame and having a predetermined arc in an outer circumferential direction, a driven gear portion formed along an outer circumferential surface of the moving plate, a driving gear meshed with the driven gear portion, and a driving motor for rotating the driving gear A wastewater treatment device comprising a.

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