KR101705341B1 - Automatic Sewage water treatment apparatus by ozone - Google Patents

Abstract

The present invention relates to an automatic sewage water treatment apparatus by ozone. The apparatus sterilizes virus, E. coli, etc. in effluent by inputting ozone into effluent through an ozone input means, removes ozone remaining in effluent by an electrolysis means and ultraviolet irradiation means, and discharges ozone through a final discharge pipe to an effluent system such as the river or the like. Accordingly, pollution of an effluent system and the source of water can be prevented. Also, since ozone used in sterilization is removed and discharged into an effluent system, damage caused by residual ozone can be prevented.

Description

Technical Field [0001] The present invention relates to an automatic sewage treatment apparatus by ozone,

The present invention relates to an automatic sewage treatment apparatus using ozone, and more particularly, to an apparatus for treating sewage, which is capable of preventing contamination of a discharged water system and contamination of a water supply source by disinfecting discharged water immediately before it is discharged to a discharge water system, The present invention relates to an automatic sewage treatment apparatus using ozone, which is capable of eliminating damage due to residual ozone by discharging it to an effluent water system after removing ozone used in treatment.

Most sewage treatment plants such as a sewage end treatment plant, a wastewater end treatment plant, or a village sewage treatment plant filter out solid matters contained in the raw water to be purified and decompose or coagulate the organic matter, purify the biomass to a required amount of biochemical oxygen, .

There are many facilities that do not sufficiently disinfect the virus or Escherichia coli, or discharge it at all.

In this way, when discharging without disinfection treatment for viruses, Escherichia coli, etc. at the sewage treatment plant, the water supply source is contaminated. Therefore, regulations related to disinfection treatment of sewage treatment plants are strengthened.

However, adding sterilization facilities to existing sewage treatment plants is technically and spatially constrained.

Accordingly, as a prior art related to a disinfection facility of a conventional sewage disposal plant, Korean Utility Model Registration No. 20-0352280 (registered May 25, 2004) discloses a water level detection unit for detecting a water level introduced into a discharge tank, The ozone generator provided to supply the ozone to the disinfection tank, and the pump and ozone generator when the set high-level arrival signal is received from the water level detection unit, and sterilized by the ozone supplied from the disinfection tank And a control unit for stopping the operation of the pump and the ozone generator when the low level arrival signal is received from the water level detection unit. Thus, disinfection treatment for the discharged water can be automatically performed while utilizing the conventional purification treatment facility as it is, It is possible to increase the efficiency of sterilization treatment while reducing the amount of ozone used, And to work, and a simple automatic start of the ozone disinfection device for sewage treatment by installing a dilution tank and electric cracker to reduce the amount of ozone to increase the sterilization efficiency.

However, in the prior art, since the discharged water of the discharge tank is transferred to the disinfection tank by the pump and the disinfected water of the disinfection tank is transferred to the dilution tank again by the pump, the power consumption is increased and the final discharge water finally discharged through the disinfection tank and dilution tank is discharged It is discharged to the discharge water system through the conduit. In this process, there is a fear that the virus or Escherichia coli may be contaminated again, so that disinfection proceeded at the discharge stage becomes useless.

Therefore, it is required to develop a technique for preventing contamination of the discharged water system and contamination of the water supply source, in particular, by disinfecting the discharged water immediately before the discharged water is discharged to the discharged water system.

Korea Registered Utility Model No. 20-0352280 (Registered on May 25, 2004.) "Ozone automatic disinfection device for simple sewage treatment"

Accordingly, it is an object of the present invention to prevent contamination of the discharged water system and contamination of the water supply source by disinfecting the discharged water immediately before being discharged to the discharge water system, and to remove the ozone used in the sterilization treatment and discharge it to the discharge water system, And to provide an automatic sewage treatment apparatus using ozone.

In order to achieve the above object, the present invention provides a sewage disposal system including a first expansion conduit connected to a terminating end of a discharge pipe connected to a sewage treatment plant and having a width greater than a width of the discharge pipe, A second expansion conduit connected to a downstream side of the first expansion conduit through a first connection conduit formed to have a width larger than a width of the outlet conduit and formed to have a width equal to the width of the outlet conduit; A third expansion conduit connected to the downstream side of the second expansion conduit through the second connection conduit and formed to have a width larger than the width of the discharge conduit, a third expansion conduit connected to the downstream side of the third expansion conduit, A conduit including a final discharge conduit formed in the same width; A plurality of partition walls defining a zigzag flow passage in the first expansion conduit; Ozone input means for inputting ozone into the expansion conduit; Circulation means for sucking and re-introducing the effluent water in the expansion conduit to increase the mixing efficiency of the effluent water and ozone; An electrolytic unit installed in the second expansion conduit to electrolyze discharged water; An ultraviolet irradiator installed in the third expansion conduit and irradiating ultraviolet rays to the effluent water; And power supply means for generating electricity using the discharged water discharged from the final discharge conduit and supplying power to the ozone injection means, the circulation means, the electrolysis means and the ultraviolet ray irradiation means, A first extension conduit, a second expansion conduit, a second expansion conduit, a third expansion conduit, a third expansion conduit, and a final outlet conduit, the outlet conduit body having a bottom and a front and rear wall, A first expansion conduit body, a first expansion conduit body, a second expansion conduit body, a second connection conduit body, a third expansion conduit body and a final outlet conduit body, an outlet conduit cover covering the upper opening portion, A second expansion conduit cover, a second expansion conduit cover, a third expansion conduit cover, and a final outlet conduit cover, wherein the ozone input means comprises an ozone supply unit installed at an upper portion of the expansion conduit, An ozone input header formed at a lower end portion of the partition wall; an ozone input hole penetrating the lower surface and the upstream and downstream side surfaces of the ozone input header for inputting ozone into the discharge water; An ozone injection tube portion opened at an upper end surface of the partition wall and an ozone injection tube connecting the ozone generator and an upper end of the ozone injection tube portion and an ozone injection pump provided in the ozone injection tube, A suction header formed on the partition wall at an upper portion of the ozone introduction header and having a plurality of suction holes formed on an upstream side and a downstream side thereof, and a plurality of suction holes formed in the partition wall between the ozone injection header and the suction header, A suction header having a lower end connected to the suction header and an upper end opened at an upper end surface of the partition wall; A suction pipe connected to an upper end of the suction pipe unit and connected to an upper end of the re-inflow pipe unit; and a suction pipe connected to a lower end of the re- And a circulation pump having a suction end connected to the suction pipe and a discharge end connected to the re-inlet pipe, wherein the electrolysis means includes: a plurality of partition walls defining a zigzag flow path in the second expansion pipe; A cathode plate and a cathode plate attached to the opposite surfaces of the barrier ribs, and a power source for electrolysis for applying an electric power for electrolysis to the cathode and anode plates, A lamp housing housed in the lamp housing and having ultraviolet rays inside the third expansion conduit, Wherein the power supply means comprises a pair of front and rear supports coupled to a downstream side of the final discharge pipe, a turbine rotatably installed on the support, A rectifier and a charging circuit for converting an AC generated from the generator into a direct current; a charging battery charged by the charging circuit; and a rectifier for charging the direct current of the charging battery to the ozone generator, And an inverter for converting an AC signal for an ultraviolet lamp to a circulation pump, an electrolysis power source unit, and an automatic sewage treatment apparatus using ozone.

According to the ozone automatic sewage treatment apparatus of the present invention, ozone is injected into the effluent water by the ozone injecting means to sterilize viruses, E. coli and the like in the effluent water, and ozone remaining in the effluent water is removed by the electrolytic means and the ultraviolet irradiation means It is possible to prevent contamination of the effluent system and pollution of the water source by discharging to the discharge water system such as river through the next final discharge channel, and to remove the ozone used for sterilization treatment and discharge to the discharge water system, .

1 to 10 show a preferred embodiment of an automatic sewage treatment apparatus using ozone according to the present invention,
1 is an overall perspective view of an automatic sewage treatment apparatus using ozone according to the present embodiment,
Fig. 2 is an exploded perspective view of the conduit according to the present embodiment,
3 is an exploded perspective view of the ozone input means and the circulation means,
4 is an exploded perspective view of the electrolysis means,
5 is an exploded perspective view of ultraviolet irradiation means,
6 is an exploded perspective view of the power supply means,
7 is a cutaway perspective view of a partition wall showing an ozone introduction header, an ozone introduction hole, and an ozone introduction tube portion,
8 is a cutaway perspective view of a partition wall showing a suction header, a suction hole and a suction pipe portion,
9 is a cutaway perspective view of a partition wall having a re-inflow header and re-inflow and re-
10 is a block diagram showing the power supply system.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an automatic sewage treatment apparatus using ozone according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 10 show a preferred embodiment of an automatic sewage treatment apparatus using ozone according to the present invention.

The automatic sewage treatment apparatus using ozone according to the present embodiment is installed at the end of a discharge duct connected to a final sedimentation tank of a sewage treatment plant (not shown) to transfer discharged water to a discharge water system such as a river, As shown in FIG.

The automatic wastewater treatment apparatus according to the present embodiment includes a first expansion conduit 120 connected to a terminating end of a discharge conduit 110 connected to a sewage treatment plant and having a width greater than the width of the discharge conduit 110, And a second connection pipe 130 connected to a downstream side of the first expansion pipe 120 through a first connection pipe 130 formed to have the same width as the width of the discharge pipe 110, A second expansion conduit 140 formed to have a width equal to the width of the outlet conduit 110 and a second connection conduit 150 having a width equal to the width of the outlet conduit 110, A third expansion conduit 160 formed to have a width greater than the width of the discharge conduit 110 and a second expansion conduit 160 connected to a downstream side of the third expansion conduit 160 and formed to have the same width as the width of the discharge conduit 110 A conduit 100 including a final outlet conduit 170 that is connected to the outlet conduit 170; A plurality of partition walls 200 forming a staggered flow path in the first expansion conduit 120; An ozone input means 300 for inputting ozone into the first expansion conduit 120; Circulation means (400) for sucking and re-introducing the effluent water in the first expansion conduit (120) to increase the mixing efficiency of the effluent water and ozone; An electrolysis means (500) installed in the second expansion conduit (140) for electrolyzing effluent water; An ultraviolet irradiator 600 installed in the third expansion conduit 160 to emit ultraviolet rays to the effluent water; Electricity is generated using the discharged water discharged from the final discharge pipe 170 and power is supplied to the ozone injecting means 300, the circulating means 400, the electrolyzing means 500 and the ultraviolet irradiating means 600 And power supply means 700.

The first expansion conduit 120, the first connection conduit 130, the second expansion conduit 140, the second connection conduit 150, the third expansion conduit 160, and the final outlet conduit 160, The first expansion conduit main body 121, the first connection conduit main body 131, the second expansion conduit main body 131, the second expansion conduit main body 131, A first expansion conduit cover 141, a second connection conduit main body 151, a third expansion conduit main body 161 and a final discharge conduit main body 171, an outlet duct cover 112 for covering the top open portion, A second expansion conduit cover 122, a first connection conduit cover 132, a second expansion conduit cover 142, a second connection conduit cover 152, a third expansion conduit cover 162 and a final outlet conduit cover 172 (See Fig. 2).

The first expansion conduit main body 121, the first connection conduit main body 131, the second expansion conduit main body 141, the second connection conduit main body 151, the third expansion conduit main body 161 and the final outlet conduit body 171 and the outlet conduit cover 112, the first expansion conduit cover 122, the first connection conduit cover 132, the second expansion conduit cover 142, The conduit cover 152, the third expansion conduit cover 162 and the final outlet conduit cover 172 may all be constructed of a concrete structure and the outlet conduit cover 112, the first expansion conduit cover 122, The first conduit cover 132, the second expansion conduit cover 142, the second conduit cover 152, the third expansion conduit cover 162 and the final outlet conduit cover 172 may be constructed of metal or synthetic resin It is possible.

The first expansion conduit cover 122 is provided with an ozone input pipe through-hole 123 through which the ozone input pipe 350 of the ozone input means 300 described later passes and a suction pipe 450 of the circulation means 400, A through hole 125 through which the suction pipe through hole 124 and a reintroduction pipe 460 of the circulation means 400 to be described later penetrate is formed.

The third expansion conduit cover 162 is formed so that ultraviolet rays generated by the ultraviolet irradiation unit 600 to be described later can be irradiated onto the discharge water in the third expansion conduit 162 by forming the transparent hole 163.

The partition wall 200 may be formed of a synthetic resin so as to form a part of the ozone input means 300 and the circulation means 400, which will be described later.

The partition wall 200 is formed by inserting one end of the lower end portion and the front and rear end portions into the coupling groove 126 formed in the bottom of the first extension pipe main body 121 and the front and rear inner walls, (Not shown) is filled in the clearance between the upper and lower plates.

The ozone input means 300 includes an ozone generator 310 installed at an upper portion of the first expansion conduit 120, an ozone injection header 320 formed at a lower end of the partition 200, An ozone injection hole 330 through which the ozone is injected into the discharge water, and a lower end connected to the ozone injection header 320 and having an upper end connected to the upper end of the partition wall 200, An ozone injection pipe 350 connecting the ozone generator 310 and an upper end of the ozone injection pipe 340 and an ozone injection pump 360 installed in the ozone injection pipe 350. [ ).

An extension portion 341 for inserting and connecting the lower end of the ozone introduction pipe 350 is formed at an upper end of the ozone injection pipe portion 340.

The circulation means 400 includes a suction header 410 formed on the partition 200 at an upper portion of the ozone input header 320 and having a plurality of suction holes 411 formed on an upstream side and a downstream side thereof, A re-entry header 420 formed in the partition 200 between the header 320 and the intake header 410 and having a plurality of re-entry holes 421 formed on the upstream side and the downstream side, A lower end connected to the upper end of the partition wall 200 and having an upper end opened at an upper end surface of the partition 200 and a lower end connected to the lower end of the re- A suction pipe 450 connected to an upper end of the suction pipe unit 430 and a reintroduction pipe 460 connected to an upper end of the reintroduction pipe unit 440 and a suction pipe 450 connected to the suction pipe 450, And a circulation pump 470 having a suction end connected to the inlet pipe 460 and a discharge end connected to the re-inlet pipe 460.

An extension 431 for inserting and connecting the lower end of the suction pipe 450 is formed at an upper end of the suction pipe 430 and a lower end of the re- An extension portion 441 for connection is formed.

The partition wall 200 is connected to the ozone input header 320, the ozone input hole 330 and the ozone input pipe portion 340 and the suction header 410, the re-entry header 420, the suction pipe portion 430, It is preferable to form the upstream tube portion and the downstream tube portion by means of high-frequency bonding (see FIGS. 7 to 9) so that the inlet tube portion 440 can be formed.

The electrolytic means 500 includes a plurality of partition walls 510 forming a staggered flow path in the second expansion conduit 140 and a cathode plate 520 attached to the opposing surfaces of the partition walls 510, A cathode plate 530 and an electrolytic power supply unit 540 for applying an electric power for electrolysis to the cathode plate 520 and the cathode plate 530.

The partition wall 510 and the cathode plate 520 and the cathode plate 530 are formed by inserting either the lower end portion or the front and rear end portions into the coupling groove 143 formed in the bottom of the second extension pipe body 141 and the front and rear inner walls, It is preferable that a filler (not shown) is filled in the gap between the groove 143 and the partition 510, the positive electrode plate 520, and the negative electrode plate 530 and is installed in a watertight state.

The ultraviolet irradiating means 600 includes a lamp housing 610 which is covered on the upper surface of the third expansion conduit cover 162 and has a reflection surface 620 on the inner surface thereof and a lamp housing 610 installed inside the lamp housing 610 And an ultraviolet lamp 630 that emits ultraviolet rays to the discharge water in the third expansion conduit 160.

The lamp housing 610 may be formed of a synthetic resin or a metal material and the reflecting surface 620 may be formed by plating the inner surface of the lamp housing 610 by an aluminum metal vapor plating method, have.

The lamp housing 610 is provided with a lower opening portion 640 corresponding to the light transmitting hole 163 of the third expansion pipe cover 162 and a lower opening portion 640 formed at the lower edge thereof on the upper surface of the third expansion pipe cover 162 A corresponding flange portion 650 is provided.

The ultraviolet lamp 630 may be a conventional ultraviolet lamp, and a lamp socket (not shown) may be installed inside the lamp housing 610 to install the ultraviolet lamp 630, And a stabilizer 660 for lighting the ultraviolet lamp 630 is installed on the upper surface.

The power supply means 700 includes a pair of front and rear supports 710 coupled to the downstream side of the final discharge pipe 170, a turbine 720 rotatably installed on the support 710, A generator 730 having a generator shaft 731 coupled to a rotary shaft 721 of the generator 720, a rectifying and charging circuit 740 for converting AC generated in the generator 730 into DC, A circulation pump 470 and an electrolytic power supply unit 540. The ozone generator 700 is connected to the ozone generator 310 through the ozone supply pump 360, And an inverter 760 for converting the light into an alternating current for the ultraviolet lamp 630.

The charging circuit 740, the rechargeable battery 750, and the inverter 760 can be installed on the upper portion of the second expansion conduit cover 152, which will be replaced with a circuit diagram (see FIG. 9).

A protection cover (not shown) is installed on the upper portion of the first expansion conduit 120 to protect the ozone generator 310, the ozone introduction pump 360, the circulation pump 470 and the respective pipes from snow or other foreign matter And a protective cover (not shown) may be installed on the second expansion conduit 140 to protect the electrolytic power supply unit 540 from snow or other foreign matter.

Further, the ballast 660 may be installed inside the lamp housing 610 to protect it from snow or other foreign matter.

Hereinafter, a process of treating effluent water by an automatic sewage treatment apparatus using ozone according to the present embodiment will be described.

When waste water treated in the sewage treatment plant and discharged through the discharge pipe 110 flows into the first expansion pipe 120, the water flows along the zigzag flow path by the zigzag installed partition 200 and flows into the first expansion pipe 120 ) Is prolonged.

At this time, the ozone generated in the ozone generator 310 of the ozone input means 300 installed in the first expansion conduit 120 is pumped by the ozone injection pump 360 to be formed in the ozone injection pipe 350 and the partition 200 Is supplied to the ozone input header 320 through the ozone input tube portion 340 and flows through the ozone input header 330 formed in the upstream side and the downstream side of the ozone input header 320, Is discharged into the discharge water.

Ozone introduced into the effluent water sterilizes viruses and E. coli in the effluent water. Since the discharged water flowing in the first expansion conduit 120 flows in a staggered shape by the partition 200 and the residence time is prolonged, the sterilizing effect by the applied ozone increases accordingly.

The discharged water in the first expansion conduit 120 is sucked through the suction hole 411 formed in the partition 200 by the pumping action of the circulation pump 470 and the suction header 410 and the suction pipe portion 430 connected to the suction header 410 And is introduced into the first expansion conduit 120 through the re-inlet pipe 460, the re-inlet pipe 440, the re-inlet header 420 and the re-entry hole 421, And is circulated in such a way that it flows in.

In this circulation process, the effluent and the ozone injected into it are mixed more actively, so that the entire discharge water is uniformly sterilized.

The effluent water sterilized by the ozone input means 300 and the circulation means 400 in the first expansion conduit 120 flows into the second expansion conduit 140 through the first connection conduit 130.

The discharge water flowing into the second expansion conduit 140 flows in a zigzag manner by the partition wall 510 and the residence time is prolonged.

At this time, the positive electrode plate 520 and the negative electrode plate 530 are attached to the partition wall 510. Since power for electrolysis is applied to the positive electrode plate 520 and the negative electrode plate 530 from the power source for electrolysis 540, 2 Ozone remaining in the discharged water flowing through the expansion conduit 140 is electrolyzed and removed.

The effluent water flowing through the second expansion conduit 140 and having the remaining ozone removed by the electrolytic means 500 flows into the third expansion conduit 160 through the second connection conduit 150.

At this time, a lamp housing 610 is installed on the upper portion of the third expansion conduit 160, and an ultraviolet lamp 630 is installed in the lamp housing 610. Since power is supplied to the ultraviolet lamp 630 through the ballast 660 Ultraviolet rays are irradiated to the discharged water flowing into the third expansion conduit 160.

Ultraviolet irradiation of the discharged water decomposes and removes ozone remaining in the discharged water.

Therefore, sterilization by ozone and removal of residual ozone are effectively performed, and even when discharged to a discharged water system such as a river at the end, there is no adverse effect on water quality.

On the other hand, the discharged water passing through the third expansion conduit 160 is discharged to a discharge water system such as a river through the final discharge conduit 170. At this time, a pair of support platforms 710 are installed in the final discharge conduit 170 The aberration 720 is rotatably installed on the supporter 710 so that the aberration 720 is rotated by the discharged water and the power generator shaft 731 is coupled to the rotation axis 721 of the aberration 720 The generator 730 is rotated and AC power is generated.

The alternating current generated by the generator 730 is converted into a direct current by the charging circuit 740 to be charged into the rechargeable battery 750 and the direct current charged in the rechargeable battery 750 is again converted into an alternating current by the inverter 760 The ozone is supplied as power to the ozone generator 310, the ozone injection pump 360, the circulation pump 470, the power supply unit 540 and the ultraviolet lamp 630 so as to be supplied to the ozone injection means 300, the circulation means 400, The ultraviolet ray irradiation means 500 and the ultraviolet ray irradiation means 600 can be operated.

On the other hand, when the power generation capacity of the generator 730 using the discharged water is not sufficient to operate the ozone input means 300, the circulation means 400, the electrolytic means 500 and the ultraviolet irradiation means 600, Battery 750 may be constructed with a conventional distributed power system in combination with conventional utility electricity and additional solar power systems.

As described above, according to the ozone automatic sewage treatment apparatus of this embodiment, ozone is injected into the effluent water by the ozone injecting means to sterilize viruses, E. coli and the like in the effluent water, and by the electrolytic means and ultraviolet irradiation means The ozone remaining in the effluent is removed and the effluent is discharged to the effluent system such as a river through the final discharge channel to prevent contamination of the effluent system and pollution of the water source. In addition, ozone used in the disinfection treatment is removed, The damage caused by ozone can be excluded.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or essential characteristics thereof. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

110: Discharge conduit 120: First expansion conduit
140: Second Expansion Dwell 160: Third Expansion Dwell
170: Final discharge channel 200:
300: ozone input means 310: ozone generator
320: Ozone input header 330: Ozone input nozzle
340: ozone feed pipe 350: ozone feed pipe
360: ozone injection pump 400: circulation means
410: Suction header 420: Re-inflow header
430: suction pipe part 440: re-
450: suction pipe 460:
470: circulation pump 500: electrolysis means
510: partition wall 520: positive electrode plate
530: cathode plate 540: power source for electrolysis
600: ultraviolet irradiation means 610: lamp housing
620: Reflecting surface 630: Ultraviolet lamp
700: power supply means 710: support
720: aberration 730: generator
740: Charging circuit 750: Rechargeable battery
760: Inverter

Claims (1)

A first expansion conduit 120 connected to a terminating end of the discharge conduit 110 connected to the sewage treatment plant and having a width greater than the width of the discharge conduit 110, A second expansion conduit 140 connected to a downstream side of the first expansion conduit 120 through a first connection conduit 130 formed in the first expansion conduit 130 and having a width greater than that of the discharge conduit 110, The outlet pipe 110 is connected to the downstream side of the second expansion pipe 140 through a second connection pipe 150 having a width equal to the width of the discharge pipe 110, A conduit 100 including a third expansion conduit 160 and a final discharge conduit 170 connected to the downstream side of the third expansion conduit 160 and having a width equal to the width of the discharge conduit 110, Wow;
A plurality of partition walls 200 forming a staggered flow path in the first expansion conduit 120;
An ozone input means 300 for inputting ozone into the first expansion conduit 120;
Circulation means (400) for sucking and re-introducing the effluent water in the first expansion conduit (120) to increase the mixing efficiency of the effluent water and ozone;
An electrolysis means (500) installed in the second expansion conduit (140) for electrolyzing effluent water;
An ultraviolet irradiator 600 installed in the third expansion conduit 160 to emit ultraviolet rays to the effluent water;
Electricity is generated using the discharged water discharged from the final discharge pipe 170 and power is supplied to the ozone injecting means 300, the circulating means 400, the electrolyzing means 500 and the ultraviolet irradiating means 600 And power supply means 700,
The first expansion conduit 120, the first connection conduit 130, the second expansion conduit 140, the second connection conduit 150, the third expansion conduit 160, and the final outlet conduit 160, The first expansion conduit main body 121, the first connection conduit main body 131, the second expansion conduit main body 131, the second expansion conduit main body 131, A first expansion conduit cover 141, a second connection conduit main body 151, a third expansion conduit main body 161 and a final discharge conduit main body 171, an outlet duct cover 112 covering the top openings, A second expansion duct cover 122, a first connection duct cover 132, a second expansion duct cover 142, a second connection duct cover 152, a third expansion duct cover 162 and a final discharge duct cover 172,
The ozone input means 300 includes an ozone generator 310 installed at an upper portion of the first expansion conduit 120, an ozone injection header 320 formed at a lower end of the partition 200, An ozone injection hole 330 through which the ozone is introduced into the discharge water and a lower end connected to the ozone injection header 320 and an upper end connected to the upper end of the partition wall 200, And an ozone injection pipe 350 for connecting the ozone generator 310 and the upper end of the ozone injection pipe part 340. The ozone injection pipe 350 is connected to the ozone injection pipe 350, (360)
The circulation means 400 includes a suction header 410 formed on the partition 200 at an upper portion of the ozone input header 320 and having a plurality of suction holes 411 formed on an upstream side and a downstream side thereof, A re-entry header 420 formed in the partition 200 between the header 320 and the intake header 410 and having a plurality of re-entry holes 421 formed on the upstream side and the downstream side, A lower end connected to the upper end of the partition wall 200 and having an upper end opened at an upper end surface of the partition 200 and a lower end connected to the lower end of the re- A suction pipe 450 connected to an upper end of the suction pipe unit 430 and a reintroduction pipe 460 connected to an upper end of the reintroduction pipe unit 440 and a suction pipe 450 connected to the suction pipe 450, And a circulation pump 470 having a suction end connected to the inlet pipe 460 and a discharge end connected to the re-inlet pipe 460,
The electrolytic means 500 includes a plurality of partition walls 510 forming a staggered flow path in the second expansion conduit 140 and a cathode plate 520 attached to the opposing surfaces of the partition walls 510, And an electrolytic power supply unit 540 for applying a power for electrolysis to the positive electrode plate 520 and the negative electrode plate 530,
The ultraviolet irradiating means 600 includes a lamp housing 610 which is covered on the upper surface of the third expansion conduit cover 162 and has a reflection surface 620 on the inner surface thereof and a lamp housing 610 installed inside the lamp housing 610 And an ultraviolet lamp (630) for irradiating ultraviolet rays to the discharge water in the third expansion conduit (160)
The power supply means 700 includes a pair of front and rear supports 710 coupled to the downstream side of the final discharge pipe 170, a turbine 720 rotatably installed on the support 710, A generator 730 having a generator shaft 731 coupled to a rotary shaft 721 of the generator 720, a rectifying and charging circuit 740 for converting AC generated in the generator 730 into DC, A circulation pump 470 and an electrolytic power supply unit 540. The ozone generator 700 is connected to the ozone generator 310 through the ozone supply pump 360, And an inverter (760) for converting the ultraviolet lamp (630) into an alternating current for the automatic wastewater treatment apparatus.

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