JP3233022U - Lake eutrophication treatment facility - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a eutrophication treatment facility for a lake having a rational structure and a compact structure. SOLUTION: The enrichment treatment equipment includes a water transport pipe 1, an aeration tank 2, a bracket 3, a mud drain pipe 4, a sludge tank 5, an aeration device 6, an ozone supply chamber 7, a communication pipe 8, an ultraviolet excitation chamber 9, and the like. Including a water purification pipe 10, a floating platform 11, and a control system 12, the aeration tank is connected to the lower lake via a water transport pipe, and a water pump is provided in the water transport pipe between the bottom of the aeration tank and the sludge tank. Is provided with a mud drain pipe, an electromagnetic valve is provided at the end of the mud drain pipe, a bracket is provided below the aeration tank, a floating platform is provided below the bracket, and the floating platform mounts all members. Float on the surface of the lake, an aeration tank is provided on the surface of the floating platform, a gas injection port is provided at the bottom of the aeration tank, the gas injection port communicates with the aeration device, and the aeration device connects the pipeline. It is connected to the ozone supply chamber via a communication tube, and the aeration tank communicates with the ultraviolet excitation chamber 9 via a communication pipe. [Selection diagram] Fig. 1

Description

The present invention relates to the field of lake pollution control equipment, and specifically to the eutrophication treatment equipment for lakes.

Under the conditions of the prior art, the processing equipment and related technologies in this field are not yet mature, and the prior art mainly lacks the following mechanisms.

That is, there are no water transport pipes, aeration tanks, brackets, mud drain pipes, sludge tanks, aeration devices, ozone supply chambers, communication pipes, ultraviolet excitation chambers, water purification pipes, floating platforms, and control system mechanisms.

Since the above mechanism is absent or the above mechanism is not mature, there are drawbacks such as an old process, high processing cost, low operating efficiency, long process flow, uncontrollable automatic control, and large occupied area. ..

In order to solve the above technical problems, the present invention provides a lake enrichment treatment facility, which is a water transport pipe 1, an aeration tank 2, a bracket 3, and a mud drainage pipe. 4. Includes a sludge tank 5, an aeration device 6, an ozone supply chamber 7, a communication pipe 8, an ultraviolet excitation chamber 9, a water purification pipe 10, a floating platform 11, and a control system 12.
The aeration tank 2 is connected to a lower lake via a water transport pipe 1, a water pump is provided in the water transport pipe 1, and a mud drain pipe 4 is provided between the bottom of the aeration tank 2 and the sludge tank 5. An electromagnetic valve is provided at the end of the mud drain pipe 4, a bracket 3 is provided below the aeration tank 2, a floating platform 11 is provided below the bracket 3, and the floating platform 11 mounts all members. It is placed and floats on the surface of the lake, an aeration tank 2 is provided on the surface of the floating platform 11, a gas injection port is provided at the bottom of the aeration tank 2, and the gas injection port communicates with the aeration device 6. The aeration device 6 is connected to the ozone supply chamber 7 via a conduit, the aeration tank 2 communicates with the ultraviolet excitation chamber 9 via a communication pipe 8, and a water purification pipe is connected to the side wall of the ultraviolet excitation chamber 9. 10 is provided, the control system 12 is located on the surface of the floating platform 11, and a water pump and an electromagnetic valve are connected to the control system 12 via a lead wire.

Further, the aeration tank 2 includes an aeration tank case 21, a horizontal filtration baffle 22, an inclined flow guide plate 23, a vertical partition plate 24, a water level sensor 25, a collection chamber 26, and an aeration head 27.
The inclined flow guide plate 23 is located on the left side inside the aeration tank case 21, the upper end thereof is an arcuate plate bent upward, and the lower portion is a inclined plate inclined by 10 ° to 45 °. Both sides of 23 are seamlessly welded to the inner wall of the aeration tank case 21, the horizontal filtration baffle 22 is horizontally arranged at the bottom of the inclined flow plate 23, and the right wall of the horizontal filtration baffle 22 is the inclined flow plate 23. The remaining side wall is seamlessly welded to the inner wall of the aeration tank case 21, a large number of through holes are evenly distributed on the surface of the horizontal filtration baffle 22, and the vertical partition plate 24 is inclined. Arranged perpendicular to the position of the bottom of the diversion plate 23, the top surface of the vertical partition plate 24 is seamlessly welded to the bottom of the inclined diversion plate 23, and the remaining side walls are seamlessly welded to the inner wall of the aeration tank case 21. A water level sensor 25 is provided inside the air exposure tank 2, the water level sensor 25 is connected to the control system 12 via a lead wire, and a collection chamber 26 for collecting sediment is provided below the horizontal filtration baffle 22. At the bottom of the air-exhaust tank case 21, an air-exhausting device 6 is provided, one end of which communicates with an external air pump and the other end of which communicates with a plurality of air-exhaust heads 27.

Further, the aeration head 27 includes a duct 271, a dust adsorption block 272, a hot air ring 273, a valve 274, an exhaust passage 275, a microbial growth agent nozzle 276, a dust filtration net 277, and an air supply passage 278.
The exhaust passage 275 at one end is provided with a valve 274 at its output port, the valve 274 is connected to the control system 12 via a lead wire, and a microbial growth agent nozzle 276 is provided inside the left side of the exhaust passage 275. The microbial growth agent nozzle 276 has a trumpet shape, opens to the left, is connected to an external microbial growth agent via a tube, has a hot air ring 273 on the left side of the microbial growth agent nozzle 276, and has a hot air ring 273. A large number of through holes are provided on the left side of the ring surface, and a dust filtration net 277, a dust suction block 272, a duct 271, and an air supply passage 278 are sequentially provided on the left side of the hot air ring 273.

Furthermore, the operation method of the equipment is
The control system 12 activates the water pump of the water transport pipe 1 to send lake water into the aeration tank 2, and also activates the aeration device 6 to inject a large amount of gas from the gas injection port at the bottom of the aeration tank 2 to contaminate the aeration tank 2. The lake water is aerated, the control system 12 opens the electromagnetic valve at the end of the mud drain pipe 4, discharges the sludge from the aeration to the sludge tank 5 through the sludge pipe 4, and after 5 min to 100 min aeration treatment, the aeration device. 6 sends the ozone in the ozone supply chamber 7 to the aeration tank 2 from the gas injection port to treat the water, and the communication pipe 8 sends the water in the aeration tank 2 to the aeration chamber 9 and irradiates the aeration chamber 9. In step 1, the control system 12 opens the electric control valve passing through the water purification pipe 10 to discharge the purified water to the lake, further killing harmful microorganisms.
During the operation of the aeration tank 2, the lake water to be treated enters the inside of the aeration tank 2 from the right side along the side wall, the aeration device 6 aerates the lake water to be treated by a plurality of aeration heads 27, and the sediment is an inclined flow plate. Along the slope of 23, it passes through the through hole of the horizontal filtration baffle 22 and enters the collection chamber 26, the treated water is discharged from a high place on the right side of the aeration tank 2, and the water level is at the top of the aeration tank 2. Step 2 in which the sensor 25 is provided and the operational safety of the water level of the aeration tank 2 is monitored in real time, and
During the operation of the aeration head 27, air enters from the air supply passage 278, passes through the duct 271, the dust adsorption block 272, and the dust filtration network 277 in order, the dust in the air is removed, and the temperature is 40 ° C to 60 ° C by the hot air ring 273. The hot air of the microbial growth agent promotes the growth of microorganisms, the microbial growth agent ejected from the microbial growth agent nozzle 276 promotes the growth of microorganisms, and finally includes step 3 of injecting gas through the valve 274.

The advantages of the present invention are that the structure is rational and compact, the effect of use is high, the process is new, and the range of equipment is wide.

It is a figure of the eutrophication treatment facility of the lake of this invention. It is a figure of the aeration tank 2 of this invention. It is a figure of the aeration head 27 of this invention.

Hereinafter, the lake eutrophication treatment facility according to the present invention will be further described with reference to the drawings.

FIG. 1 is a diagram of the eutrophication treatment facility for the lake of the present invention. Water transport pipe 1, aeration tank 2, bracket 3, mud drain pipe 4, sludge tank 5, aeration device 6, ozone supply chamber 7, communication pipe 8, ultraviolet excitation chamber 9, water purification pipe 10, floating platform 11, control system 12 Including
The aeration tank 2 is connected to a lower lake via a water transport pipe 1, a water pump is provided in the water transport pipe 1, and a mud drain pipe 4 is provided between the bottom of the aeration tank 2 and the sludge tank 5. An electromagnetic valve is provided at the end of the mud drain pipe 4, a bracket 3 is provided below the aeration tank 2, a floating platform 11 is provided below the bracket 3, and the floating platform 11 mounts all members. It is placed and floats on the surface of the lake, an aeration tank 2 is provided on the surface of the floating platform 11, a gas injection port is provided at the bottom of the aeration tank 2, and the gas injection port communicates with the aeration device 6. The aeration device 6 is connected to the ozone supply chamber 7 via a conduit, the aeration tank 2 communicates with the ultraviolet excitation chamber 9 via a communication pipe 8, and a water purification pipe is connected to the side wall of the ultraviolet excitation chamber 9. 10 is provided, the control system 12 is located on the surface of the floating platform 11, and a water pump and an electromagnetic valve are connected to the control system 12 via a lead wire.

FIG. 2 is a diagram of the aeration tank 2 of the present invention. The aeration tank 2 includes an aeration tank case 21, a horizontal filtration baffle 22, an inclined flow guide plate 23, a vertical partition plate 24, a water level sensor 25, a collection chamber 26, and an aeration head 27.
The inclined flow guide plate 23 is located on the left side inside the aeration tank case 21, the upper end thereof is an arcuate plate bent upward, and the lower portion is a inclined plate inclined by 10 ° to 45 °. Both sides of 23 are seamlessly welded to the inner wall of the aeration tank case 21, the horizontal filtration baffle 22 is horizontally arranged at the bottom of the inclined flow plate 23, and the right wall of the horizontal filtration baffle 22 is the inclined flow plate 23. The remaining side wall is seamlessly welded to the inner wall of the aeration tank case 21, a large number of through holes are evenly distributed on the surface of the horizontal filtration baffle 22, and the vertical partition plate 24 is inclined. Arranged perpendicular to the position of the bottom of the diversion plate 23, the top surface of the vertical partition plate 24 is seamlessly welded to the bottom of the inclined diversion plate 23, and the remaining side walls are seamlessly welded to the inner wall of the aeration tank case 21. A water level sensor 25 is provided inside the air exposure tank 2, the water level sensor 25 is connected to the control system 12 via a lead wire, and a collection chamber 26 for collecting sediment is provided below the horizontal filtration baffle 22. At the bottom of the air-exhaust tank case 21, an air-exhausting device 6 is provided, one end of which communicates with an external air pump and the other end of which communicates with a plurality of air-exhaust heads 27.

FIG. 3 is a diagram of the aeration head 27 of the present invention. The aeration head 27 includes a duct 271, a dust adsorption block 272, a hot air ring 273, a valve 274, an exhaust passage 275, a microbial growth agent nozzle 276, a dust filtration net 277, and an air supply passage 278.
The exhaust passage 275 at one end is provided with a valve 274 at its output port, the valve 274 is connected to the control system 12 via a lead wire, and a microbial growth agent nozzle 276 is provided inside the left side of the exhaust passage 275. The microbial growth agent nozzle 276 is trumpet-shaped, opens to the left, is connected to an external microbial growth agent via a tube, is provided with a hot air ring 273 on the left side of the microbial growth agent nozzle 276, and is a ring of the hot air ring 273. A large number of through holes are provided on the left side of the surface, and a dust filtration net 277, a dust suction block 272, a duct 271, and an air supply passage 278 are sequentially provided on the left side of the hot air ring 273.

Water transport pipe 1, aeration tank 2, bracket 3, mud drain pipe 4, sludge tank 5, aeration device 6, ozone supply chamber 7, communication pipe 8, ultraviolet excitation chamber 9, water purification pipe 10, floating platform 11, control system 12 , Aeration tank case 21, horizontal filtration baffle 22, inclined flow plate 23, vertical partition plate 24, water level sensor 25, collection chamber 26, aeration head 27, duct 271, dust suction block 272, hot air ring 273, valve 274, exhaust Passage 275, Microbial Growth Agent Nozzle 276, Dust Filtration Net 277, Air Supply Passage 278.

Claims (4)

Water transport pipe (1), aeration tank (2), bracket (3), mud drain pipe (4), sludge tank (5), aeration device (6), ozone supply room (7), communication pipe (8), A lake enrichment treatment facility that includes an ultraviolet excitation chamber (9), a water purification pipe (10), a floating platform (11), and a control system (12).
The aeration tank (2) is connected to the lower lake via a water transport pipe (1), a water pump is provided in the water transport pipe (1), and the bottom of the aeration tank (2) and the sludge tank (5). A mud drain pipe (4) is provided between the aeration pipe (4), an electromagnetic valve is provided at the end of the mud drain pipe (4), a bracket (3) is provided below the aeration tank (2), and the bracket (3) is provided. ) Is provided below the floating platform (11), the floating platform (11) is provided with all the members placed on it and floats on the surface of the lake, and the aeration tank (2) is provided on the surface of the floating platform (11). A gas injection port is provided at the bottom of the aeration tank (2), the gas injection port communicates with the aeration device (6), and the aeration device (6) communicates with the ozone supply chamber (7) via a conduit. ), The aeration tank (2) communicates with the ultraviolet excitation chamber (9) via the communication pipe (8), and a water purification pipe (10) is provided on the side wall of the ultraviolet excitation chamber (9). The aeration of the lake, characterized in that the control system (12) is located on the surface of the floating platform (11) and the water pump, the electromagnetic valve is connected to the control system (12) via a lead wire. Processing equipment. The aeration tank (2) includes an aeration tank case (21), a horizontal filtration baffle (22), an inclined flow guide plate (23), a vertical partition plate (24), a water level sensor (25), a collection chamber (26), and aeration. Including the head (27)
The inclined flow guide plate (23) is located on the left side inside the aeration tank case (21), the upper end thereof is an arcuate plate bent upward, and the lower portion is a inclined plate inclined by 10 ° to 45 °. Both sides of the inclined diversion plate (23) are seamlessly welded to the inner wall of the air exposure tank case (21), and the horizontal filtration baffle (22) is horizontally arranged at the position of the bottom of the inclined diversion plate (23) and is horizontal. The right wall of the filtration baffle (22) is seamlessly welded to the bottom of the inclined flow plate (23), the remaining side walls are seamlessly welded to the inner wall of the aeration tank case (21), and the surface of the horizontal filtration baffle (22). A large number of through holes are evenly distributed in the vertical partition plate (24), the vertical partition plate (24) is arranged vertically at the position of the bottom of the inclined flow guide plate (23), and the top surface of the vertical partition plate (24) is an inclined guide plate. It is seamlessly welded to the bottom of the flow plate (23), the remaining side walls are seamlessly welded to the inner wall of the aeration tank case (21), and a water level sensor (25) is provided inside the aeration tank (2) to provide a horizontal level. The sensor (25) is connected to the control system (12) via a lead wire, a collection chamber (26) for collecting sediment is provided under the horizontal filtration baffle (22), and an air exposure tank case (21). The lake according to claim 1, wherein an air-exhausting device (6) having one end communicating with an external air pump and the other end communicating with a plurality of air-exhausting heads (27) is provided at the bottom of the lake. Rich nutrient processing equipment. The aeration head (27) includes a duct (271), a dust adsorption block (272), a hot air ring (273), a valve (274), an exhaust passage (275), a microbial growth agent nozzle (276), and a dust filtration net (277). ), Including air supply passage (278),
The exhaust passage (275) at one end is provided with a valve (274) at its output port, the valve (274) is connected to the control system (12) via a lead wire, and the inside on the left side of the exhaust passage (275). The microbial growth agent nozzle (276) is provided in the microbial growth agent nozzle (276), and the microbial growth agent nozzle (276) has a trumpet shape, opens to the left, is connected to an external microbial growth agent via a tube, and is connected to an external microbial growth agent nozzle. A hot air ring (273) is provided on the left side of (276), a large number of through holes are provided on the left side of the ring surface of the hot air ring (273), and a dust filtration net (277) and dust are provided on the left side of the hot air ring (273). The lake enrichment treatment facility according to claim 2, wherein a suction block (272), a duct (271), and an air supply passage (278) are sequentially provided. It is a lake eutrophication treatment facility, and the operation method of the facility is
The control system (12) activates the water pump of the water transport pipe (1) to send lake water into the aeration tank (2), and activates the aeration device (6) to inject gas at the bottom of the aeration tank (2). A large amount of gas is injected from the mouth to aerate the contaminated lake water, the control system (12) opens the electromagnetic valve at the end of the mud drain pipe (4), and the sludge from the aeration is aerated through the mud drain pipe (4). After being discharged to the sludge tank (5) and aerated for 5 to 100 minutes, the aeration device (6) sends the ozone in the ozone supply chamber (7) from the gas injection port to the aeration tank (2) to treat the water. The communication pipe (8) sends the water in the aeration tank (2) to the ultraviolet excitation chamber (9) and irradiates it with ultraviolet rays to further kill harmful microorganisms, and the control system (12) is the water purification pipe (10). Open the electric control valve that goes through, and discharge the purified water to the lake, step 1 and
During the operation of the aeration tank (2), the lake water to be treated enters the inside of the aeration tank (2) from the right side along the side wall, and the aeration device (6) aerates the lake water to be treated by a plurality of aeration heads (27). , The sediment passes through the through hole of the horizontal filtration baffle (22) along the slope of the inclined flow plate (23) and enters the collection chamber (26), and the treated water is on the right side of the aeration tank (2). A water level sensor (25) is provided at the top of the aeration tank (2) to monitor the operational safety of the water level of the aeration tank (2) in real time.
During the operation of the aeration head (27), air enters from the air supply passage (278), passes through the duct (271), the dust adsorption block (272), and the dust filtration network (277) in that order, and the dust in the air is removed. , 40 ° C to 60 ° C hot air by hot aeration (273) promotes the growth of microorganisms, the microbial growth agent ejected from the microbial growth agent nozzle (276) promotes the growth of microorganisms, and finally the valve (274). A lake enrichment treatment facility comprising step 3 of injecting a gas through).

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