CN212861804U - Water body microorganism environmental monitoring drifting ball - Google Patents
Water body microorganism environmental monitoring drifting ball Download PDFInfo
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- CN212861804U CN212861804U CN202021629157.8U CN202021629157U CN212861804U CN 212861804 U CN212861804 U CN 212861804U CN 202021629157 U CN202021629157 U CN 202021629157U CN 212861804 U CN212861804 U CN 212861804U
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Abstract
The utility model provides a water microbial environment monitoring drift ball, including monitoring drift spheroid, fluorescence coating, sealed apron, solar cell panel, controller, water sample tube subassembly, stirring dial the flow pole subassembly, connect the arc, first lithium cell, second lithium cell, holding ring, hoisting ring, connect rope, counter weight anchor nail, draft lines, conductive sensor, protection casing, chlorophyll sensor, seal cover, support division board and support the design frame. The utility model is used for the little biological information such as conductivity, chlorophyll of real-time supervision surveyed water body environment to realize the real-time passback of positioning monitoring and monitoring data through GPS big dipper satellite navigation system, so that can obtain real-time continuous water environment parameter information; the fluorescent coating is arranged to play a role in preventing pollution and corrosion; when needs are taken a sample to microorganism liquid, the work of control imbibition pump is inhaled water liquid in the holding vessel, plays the effect of depositing the appearance, take when being convenient for use.
Description
Technical Field
The utility model belongs to the technical field of water monitoring facilities, especially, relate to a water microorganism environmental monitoring drift ball.
Background
The investigation shows that the water pollution condition in China is increasingly serious, and the breakthrough of a water restoration mode is imminent; the main pollution form of the existing water body is the phenomenon of eutrophication caused by overdischarge of pollutants, which causes the over-nutrition in the water body; on the other hand, with the development of agriculture in China, the use of a large amount of pesticides causes the residual pesticide components to flow into water bodies of lakes and rivers along with irrigation and drainage, so that serious water body pollution is caused, and no small influence is brought to the production and the life of human beings.
Researchers consider a water body restoration mode from multiple aspects, and focus on the aspect of treating water body pollution by microorganisms, the microorganism restoration method mainly utilizes bacteria obtained by separation, purification, domestication and screening of polluted environment components, and then uses an immobilization technology to prepare the bacteria and a carrier into an algicide, a microbial inoculum and the like, the effect of the algicide and the microbial inoculum applied to the process of restoring polluted water bodies is obvious and has pertinence, but the existing primary problem is how to fix the microbial inoculum and the algicide in the water body to achieve the purpose of restoring the water body in situ.
In addition, the invention has the name of a buoy type water body in-situ remediation device with the Chinese patent publication number of CN107162211A, and the structure of the buoy type water body in-situ remediation device comprises a buoy body, a power supply system, a power system, a microbial inoculum bin and a water quality detector; the buoy body comprises an outer shell and a rubber ring; wherein, the rubber circle is located the shell body below, and shell body both sides surface symmetry is equipped with two pull rings, and the shell body is inside to be equipped with the body filler and to be used for reinforcing device buoyancy, and the shell body top is equipped with the antenna, and the antenna links to each other with the inside power supply system of shell body. But current water body microorganism environmental monitoring drift ball still exists not being convenient for carry out the sample to aquatic microorganism and reserves, lacks the problem that promotes stirring function.
Therefore, the invention is very necessary to invent the water body microorganism environment monitoring drifting ball.
SUMMERY OF THE UTILITY MODEL
In order to solve the technical problem, the utility model provides a water microbial environment monitoring drift ball to solve current water microbial environment monitoring drift ball and be not convenient for take a sample to aquatic microorganism and keep, lack the problem that promotes stirring function.
A water body microorganism environment monitoring drifting ball comprises a drifting ball body, a fluorescent coating, a sealing cover plate, a solar cell panel, a controller, a water body sampling pipe assembly, a stirring and flow-shifting rod assembly, a connecting arc plate, a first lithium battery, a second lithium battery, a positioning ring, a hoisting ring, a connecting rope, a counterweight anchor nail, a draft line, a conductive sensor, a protective cover, a chlorophyll sensor, a sealing sleeve, a supporting and separating plate and a supporting and shaping frame;
the fluorescent coating is coated on the outer surface of the drift monitoring sphere; the sealing cover plate is connected to the upper end of the drifting monitoring sphere through bolts; the solar cell panels are respectively connected to the left side and the right side of the upper part of the sealing cover plate through bolts; the controller is connected to the supporting partition plate through bolts and is positioned in the middle of the inside of the drifting monitoring sphere; the water body sampling pipe assembly is in bolted connection with the right side position of the upper part of a supporting partition plate arranged on the upper side inside the drift monitoring sphere;
the stirring and flow-shifting rod assembly is in bolted connection with the left side position of the upper part of a supporting and separating plate arranged on the upper side inside the drift monitoring sphere; the first lithium battery and the second lithium battery are respectively connected to the left side and the right side of the lower part of the drifting monitoring sphere through screws; the positioning rings are respectively coupled to the lower part of the drifting monitoring sphere in a shaft manner and are symmetrically arranged; the draught line is longitudinally depicted in the middle of the surface of the monitoring drifting sphere;
the conductive sensor and the chlorophyll sensor penetrate through the middle position of the lower part of the monitoring drifting sphere and are connected with the controller; the protective cover is connected to the lower part of the drifting monitoring sphere through screws and covers the conductive sensor and the chlorophyll sensor; the supporting and separating plate is connected inside the drifting monitoring sphere through screws.
Preferably, the water sampling pipe assembly comprises a storage tank, a discharge conduit, a sealing cover, a liquid suction pump, a liquid inlet conduit, a liquid suction pipe and a liquid suction nozzle, wherein the sealing cover is connected with the middle position of the upper wall of the storage tank embedded with the discharge conduit in a threaded manner at the top end; one end of the liquid inlet conduit is in threaded connection with the liquid inlet end of the liquid suction pump, and the other end of the liquid inlet conduit is sleeved with the liquid suction pipe; the liquid suction nozzle is connected with the lower end of the liquid suction pipe in a threaded manner.
Preferably, the stirring flow-shifting rod assembly comprises a stirring motor, a sealing ring pad, a driving shaft, a steering turbine, a driven shaft and a stirring turbine blade, wherein the sealing ring pad is sleeved at the right side position of the outer surface of the driving shaft; one end of the driving shaft is connected with the output shaft of the stirring motor through a coupling, and the other end of the driving shaft is connected with the steering turbine; one end of the driven shaft is connected with the steering turbine, and the other end of the driven shaft is connected with a stirring turbine blade through a bolt.
Preferably, a connecting arc-shaped plate and a supporting and shaping frame are connected between the solar cell panel and the solar cell panel through screws; the connecting arc-shaped plate is positioned on the upper part of the supporting and shaping frame.
Preferably, the first lithium battery and the second lithium battery are arranged in a bilateral symmetry mode respectively.
Preferably, the hoisting ring is welded in the middle of the upper part of the connecting arc-shaped plate; the connecting arc-shaped plate is an arc-shaped stainless steel plate.
Preferably, one end of the connecting rope is riveted on the positioning ring, and the other end of the connecting rope is connected with a counterweight anchor.
Preferably, a sealing sleeve is arranged at the intersection of the conductive sensor and the chlorophyll sensor and the drift monitoring sphere.
Preferably, a plurality of supporting partition plates are arranged; the supporting partition plates are longitudinally arranged in a left-right symmetrical manner; the support division plate is transversely arranged at the upper side position inside the drifting monitoring sphere.
Preferably, the liquid suction nozzle is a conical copper nozzle; the storage tank is connected with the liquid suction pump through a pipeline.
Preferably, said discharge conduit is positioned five millimetres three millimetres from the inner lower wall of the tank.
Preferably, the upper wall of the storage tank is provided with an air outlet.
Preferably, the storage tank and the liquid suction pump are connected to the right side of the upper part of the supporting partition plate through bolts; the liquid inlet conduit is embedded in the right wall of the drifting monitoring sphere; the pipette is positioned outside the drift monitoring sphere.
Preferably, the stirring motor is connected to the left side of the upper part of the supporting partition plate through a bolt; the driving shaft is embedded in the right wall of the drifting monitoring sphere; the sealing ring pad is positioned at the intersection of the driving shaft and the drifting monitoring sphere; the steering turbine is positioned outside the drifting sphere.
Preferably, the liquid suction pump, the stirring motor, the conductive sensor and the chlorophyll sensor are respectively and electrically connected with the controller; the liquid suction pump, the stirring motor, the conductive sensor, the chlorophyll sensor and the controller are respectively and electrically connected with the first lithium battery and the second lithium battery; the first lithium battery and the second lithium battery are respectively and electrically connected with the solar panel; and a GPS/Beidou signal receiving and transmitting device is arranged in the controller.
Compared with the prior art, the beneficial effects of the utility model are that:
the water body microbial environment monitoring ball is used for monitoring the microbial information such as the conductivity and chlorophyll of the tested water body environment in real time, and realizing positioning monitoring and real-time return of monitoring data through a GPS/Beidou satellite navigation system so as to obtain real-time continuous water environment parameter information; the fluorescent coating is arranged to play a role in preventing pollution and corrosion; the solar cell panel is arranged on the upper part of the monitoring ball, and the electric energy stored by the second lithium battery can supply power for the monitoring ball to work by combining the first lithium battery; when the microorganism liquid needs to be sampled, the work of the liquid suction pump is controlled to suck the water liquid into the storage tank, so that the function of storing the sample is achieved, and the microorganism liquid is convenient to take when in use; the stirring motor is controlled to work to drive the stirring turbine blade to rotate, so that water liquid is stirred and stirred, and the effect of steering movement is achieved; the connecting rope, the balance weight anchor, the positioning ring and the hoisting ring are arranged, so that the monitoring drifting ball can be conveniently installed and fixed.
Drawings
Fig. 1 is a schematic structural diagram of the present invention.
Fig. 2 is a schematic structural view of another state of the present invention.
Fig. 3 is a schematic structural view of the water sampling tube assembly of the present invention.
Fig. 4 is a schematic structural view of the stirring flow-stirring rod assembly of the present invention.
In the figure:
1. monitoring the drifting sphere; 2. a fluorescent coating; 3. sealing the cover plate; 4. a solar panel; 5. a controller; 6. a water body sampling pipe assembly; 61. storing the tank; 62. a discharge conduit; 63. a sealing cover; 64. a liquid suction pump; 65. a liquid inlet conduit; 66. a pipette; 67. a liquid suction nozzle; 7. a stirring and flow-stirring rod assembly; 71. a stirring motor; 72. a seal ring pad; 73. a drive shaft; 74. a steering turbine; 75. a driven shaft; 76. stirring turbine blades; 8. connecting the arc-shaped plates; 9. a first lithium battery; 10. a second lithium battery; 11. a positioning ring; 12. hoisting a ring; 13. connecting ropes; 14. a counterweight anchor; 15. draft lines; 16. a conductive sensor; 17. a protective cover; 18. a chlorophyll sensor; 19. sealing sleeves; 20. supporting the partition plate; 21. and (4) supporting and shaping frames.
Detailed Description
The invention is further described below with reference to the accompanying drawings:
example (b):
as shown in fig. 1 to 2, the utility model provides a water body microorganism environmental monitoring drift ball, which comprises a monitoring drift ball body 1, a fluorescent coating 2, a sealing cover plate 3, a solar cell panel 4, a controller 5, a water body sampling tube component 6, a stirring and flow-shifting rod component 7, a connecting arc plate 8, a first lithium battery 9, a second lithium battery 10, a positioning ring 11, a hoisting ring 12, a connecting rope 13, a counterweight anchor nail 14, an draft line 15, a conductive sensor 16, a protective cover 17, a chlorophyll sensor 18, a sealing sleeve 19, a supporting and separating plate 20 and a supporting and shaping frame 21;
the fluorescent coating 2 is coated on the outer surface of the drift monitoring sphere 1; the sealing cover plate 3 is connected to the upper end of the drifting monitoring sphere 1 through bolts; the solar cell panels 4 are respectively connected to the left side and the right side of the upper part of the sealing cover plate 3 through bolts; the controller 5 is bolted on the supporting partition plate 20 and is positioned in the middle of the inside of the drifting sphere 1; the water body sampling tube assembly 6 is in bolted connection with the right side position of the upper part of a supporting partition plate 20 arranged on the upper side inside the drift monitoring sphere 1;
the stirring and flow-shifting rod assembly 7 is in bolted connection with the left side position of the upper part of a supporting and separating plate 20 arranged on the upper side inside the drift monitoring sphere 1; the first lithium battery 9 and the second lithium battery 10 are respectively connected to the left side and the right side of the lower part of the drift monitoring sphere 1 through screws; the positioning rings 11 are respectively and symmetrically arranged at the lower part of the drifting monitoring sphere 1 in a shaft connection mode;
the draft line 15 is longitudinally carved in the middle position of the surface of the monitoring drifting sphere 1; the conductive sensor 16 and the chlorophyll sensor 18 penetrate through the middle position of the lower part of the drift monitoring sphere 1 and are connected with the controller 5; the protective cover 17 is connected with the lower part of the drift monitoring sphere 1 through screws and covers the conductive sensor 16 and the chlorophyll sensor 18; the supporting division plate 20 is screwed in the inside of the drift monitoring sphere 1.
In the above embodiment, as shown in fig. 3, in particular, the water sampling pipe assembly 6 comprises a storage tank 61, a discharge conduit 62, a sealing cover 63, a liquid suction pump 64, a liquid inlet conduit 65, a liquid suction pipe 66 and a liquid suction nozzle 67, wherein the discharge conduit 62 is embedded in the middle of the upper wall of the storage tank 61 and the top end of the storage tank is in threaded connection with the sealing cover 63; one end of the liquid inlet conduit 65 is in threaded connection with the liquid inlet end of the liquid suction pump 64, and the other end of the liquid inlet conduit is sleeved with the liquid suction pipe 66; the pipette tip 67 is screwed to the lower end of the pipette 66.
As shown in fig. 4, in the above embodiment, specifically, the stirring and flow-pulling rod assembly 7 includes a stirring motor 71, a sealing washer 72, a driving shaft 73, a steering turbine 74, a driven shaft 75 and a stirring turbine blade 76, wherein the sealing washer 72 is sleeved at the right position of the outer surface of the driving shaft 73; one end of the driving shaft 73 is connected with an output shaft of the stirring motor 71 through a coupling, and the other end of the driving shaft 73 is connected with the steering turbine 74; one end of the driven shaft 75 is connected to the steering turbine 74, and the other end is bolted to the stirring turbine blade 76.
In the above embodiment, specifically, the connection arc plate 8 and the support shaping frame 21 are connected between the solar cell panel 4 and the solar cell panel 4 by screws; the connecting arc plate 8 is positioned at the upper part of the supporting and shaping frame 21.
In the above embodiment, specifically, the first lithium battery 9 and the second lithium battery 10 are respectively arranged in a left-right symmetry manner; the hoisting ring 12 is welded in the middle of the upper part of the connecting arc-shaped plate 8; the connecting arc-shaped plate 8 is an arc-shaped stainless steel plate; one end of the connecting rope 13 is riveted on the positioning ring 11, and the other end is connected with a counterweight anchor 14 through a screw.
In the above embodiment, specifically, the sealing sleeve 19 is disposed at the intersection of the conductive sensor 16 and the chlorophyll sensor 18 and the drift monitoring sphere 1.
In the above embodiment, specifically, the supporting partition plate 20 is provided in plurality; the supporting partition plate 20 is longitudinally arranged in a left-right symmetrical manner; the support division plate 20 is transversely arranged at the upper position inside the drift monitoring sphere 1.
In the above embodiment, specifically, the liquid suction nozzle 67 specifically adopts a tapered copper nozzle; the storage tank 61 is connected with a liquid suction pump 64 through a pipeline; said discharge conduit 62 is five millimetres of three millimetres from the inner lower wall of the storage tank 61; the upper wall of the storage tank 61 is provided with an air outlet.
In the above embodiment, specifically, the storage tank 61 and the liquid suction pump 64 are bolted to the right side of the upper part of the support partition plate 20; the liquid inlet conduit 65 is embedded in the right wall of the drifting monitoring sphere 1; the pipette 66 is located outside the sphere 1 for monitoring drift.
In the above embodiment, specifically, the stirring motor 71 is bolted to the left side of the upper part of the supporting partition plate 20; the driving shaft 73 is embedded on the right wall of the drift monitoring sphere 1; the sealing ring pad 72 is positioned at the intersection of the driving shaft 73 and the drifting monitoring sphere 1; the diverting turbine 74 is located outside the drift monitoring sphere 1.
In the above embodiment, specifically, the liquid suction pump 64, the stirring motor 71, the conductive sensor 16 and the chlorophyll sensor 18 are respectively electrically connected to the controller 5; the liquid suction pump 64, the stirring motor 71, the conductive sensor 16, the chlorophyll sensor 18 and the controller 5 are respectively and electrically connected with the first lithium battery 9 and the second lithium battery 10; the first lithium battery 9 and the second lithium battery 10 are respectively and electrically connected with the solar panel 4; and a GPS/Beidou signal receiving and transmitting device is arranged in the controller 5.
In the above embodiment, specifically, the steering turbine 74, the liquid suction pump 64, the stirring motor 71, the conductive sensor 16, the chlorophyll sensor 18 and the controller 5 adopt the apparatuses common in the field of mechanical communication; for example: the conductive sensor 16 is a sensor with model number HY-EC 4.0; the chlorophyll sensor 18 is a sensor with the model of ZZ-WQS-CHL-UIC; the steering turbine 74 is a steering device with model number SWL 1T.
Principle of operation
When the utility model is used, the fluorescent coating 2 is arranged to play the roles of pollution prevention and corrosion prevention; the solar cell panel 4 is arranged on the upper part of the monitoring ball, and the electric energy stored by the second lithium battery 10 can supply power for the monitoring ball to work by combining the first lithium battery 9; when the microorganism liquid needs to be sampled, the liquid suction pump 64 is controlled to work, so that the water liquid is sucked into the storage tank 61, the sample storage function is realized, and the microorganism liquid is convenient to take and use when in use; the stirring motor 71 is controlled to work to drive the stirring turbine blade 76 to rotate, so that the water liquid is stirred and stirred, and the effect of steering movement is achieved; the connecting rope 13, the counterweight anchor 14, the positioning ring 11 and the hoisting ring 12 are arranged, so that the monitoring drifting ball can be conveniently installed and fixed; the water body microorganism environment monitoring ball is used for monitoring microorganism information such as conductivity and chlorophyll of a tested water body environment in real time, and positioning monitoring and real-time returning of monitoring data are achieved through a GPS/Beidou satellite navigation system, so that real-time continuous water environment parameter information can be obtained.
In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.
Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.
Claims (10)
1. The water body microbial environment monitoring drifting ball is characterized by comprising a drifting ball body (1), a fluorescent coating (2), a sealing cover plate (3), a solar cell panel (4), a controller (5), a water body sampling pipe assembly (6), a stirring and flow-shifting rod assembly (7), a connecting arc plate (8), a first lithium battery (9), a second lithium battery (10), a positioning ring (11), a hoisting ring (12), a connecting rope (13), a balance weight anchor nail (14), a draft line (15), a conductive sensor (16), a protective cover (17), a chlorophyll sensor (18), a sealing sleeve (19), a supporting and dividing plate (20) and a supporting and sizing frame (21);
the fluorescent coating (2) is coated on the outer surface of the drift monitoring sphere (1); the sealing cover plate (3) is connected to the upper end of the drifting monitoring sphere (1) through bolts; the solar cell panels (4) are respectively connected to the left side and the right side of the upper part of the sealing cover plate (3) through bolts; the controller (5) is connected to the supporting partition plate (20) through bolts and is positioned in the middle of the inside of the drifting monitoring sphere (1); the water body sampling pipe assembly (6) is in bolted connection with the right side position of the upper part of a supporting partition plate (20) arranged on the upper side inside the drift monitoring sphere (1);
the stirring and flow-shifting rod assembly (7) is in bolted connection with the left side position of the upper part of a supporting and separating plate (20) arranged on the upper side inside the drift monitoring sphere (1); the first lithium battery (9) and the second lithium battery (10) are respectively connected to the left side and the right side of the lower part of the drift monitoring sphere (1) through screws; the positioning rings (11) are respectively coupled to the lower part of the drifting monitoring sphere (1) in a shaft manner and are symmetrically arranged; the draught line (15) is longitudinally depicted in the middle position of the surface of the monitoring drifting sphere (1);
the conductive sensor (16) and the chlorophyll sensor (18) penetrate through the middle position of the lower part of the drift monitoring sphere (1) and are connected with the controller (5); the protective cover (17) is connected to the lower part of the drift monitoring sphere (1) through screws and covers the conductive sensor (16) and the chlorophyll sensor (18); the supporting and separating plate (20) is connected inside the drift monitoring sphere (1) through screws.
2. The water body microorganism environment monitoring drifting ball of claim 1, characterized in that, the water body sampling pipe assembly (6) comprises a storage tank (61), a discharge conduit (62), a sealing cover (63), a liquid suction pump (64), a liquid inlet conduit (65), a liquid suction pipe (66) and a liquid suction nozzle (67); the middle position of the upper wall of the storage tank (61) embedded with the discharge conduit (62) is connected with a sealing cover (63) at the top end by screw thread; one end of the liquid inlet conduit (65) is in threaded connection with the liquid inlet end of the liquid suction pump (64), and the other end of the liquid inlet conduit is sleeved with a liquid suction pipe (66); the liquid suction nozzle (67) is connected with the lower end of the liquid suction pipe (66) in a threaded manner.
3. The water body microorganism environment monitoring drifting ball of claim 1, characterized in that, the stirring and flow-pulling rod assembly (7) comprises a stirring motor (71), a sealing gasket (72), a driving shaft (73), a steering turbine (74), a driven shaft (75) and a stirring turbine blade (76); the sealing ring gasket (72) is sleeved at the right side position of the outer surface of the driving shaft (73); one end of the driving shaft (73) is connected with an output shaft of the stirring motor (71) through a coupling, and the other end of the driving shaft is connected with the steering turbine (74); one end of the driven shaft (75) is connected with the steering turbine (74), and the other end of the driven shaft is connected with the stirring turbine blade (76) through a bolt.
4. The water body microorganism environment monitoring drifting ball of claim 1, characterized in that a connection arc plate (8) and a support shaping frame (21) are connected between the solar cell panel (4) and the solar cell panel (4) through screws; the connecting arc-shaped plate (8) is positioned on the upper part of the supporting and shaping frame (21).
5. The water body microorganism environment monitoring drifting ball of claim 1, characterized in that, the hoisting ring (12) is welded at the upper middle position of the connecting arc-shaped plate (8); the connecting arc-shaped plate (8) is an arc-shaped stainless steel plate.
6. The water body microorganism environment monitoring drifting ball of claim 1, characterized in that one end of the connecting rope (13) is riveted on the positioning ring (11), and the other end is screwed with a counterweight anchor (14).
7. The water body microorganism environment monitoring drifting ball of claim 1, characterized in that, a plurality of supporting division plates (20) are provided; the supporting partition plates (20) are longitudinally arranged in a left-right symmetrical manner; the supporting and separating plate (20) is transversely arranged at the upper side position inside the drift monitoring sphere (1).
8. The water body microorganism environment monitoring drifting ball of claim 2, characterized in that the liquid suction nozzle (67) is a conical copper nozzle; the storage tank (61) is connected with the liquid suction pump (64) through a pipeline.
9. The water body microorganism environment monitoring drifting ball of claim 2, characterized in that, the discharge conduit (62) is five millimeters to three millimeters from the inner lower wall of the storage tank (61).
10. The water body microorganism environment monitoring drifting ball of claim 2, characterized in that the storage tank (61) and the liquid suction pump (64) are bolted on the right side of the upper part of the supporting partition plate (20); the liquid inlet conduit (65) is embedded in the right wall of the drifting monitoring sphere (1); the pipette (66) is positioned outside the drifting sphere (1) for monitoring.
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Cited By (3)
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CN114660250A (en) * | 2022-03-14 | 2022-06-24 | 李孝清 | Sewage treatment intelligent detection system |
CN114674993A (en) * | 2022-03-14 | 2022-06-28 | 李孝清 | Sewage treatment detection method |
CN115078677A (en) * | 2022-07-22 | 2022-09-20 | 江苏建深环境科技有限公司 | Monitoring device for water pollution treatment box |
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2020
- 2020-08-07 CN CN202021629157.8U patent/CN212861804U/en active Active
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
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CN114660250A (en) * | 2022-03-14 | 2022-06-24 | 李孝清 | Sewage treatment intelligent detection system |
CN114674993A (en) * | 2022-03-14 | 2022-06-28 | 李孝清 | Sewage treatment detection method |
CN114660250B (en) * | 2022-03-14 | 2023-10-13 | 杭州希玛诺光电技术股份有限公司 | Sewage treatment intelligent detection system |
CN114674993B (en) * | 2022-03-14 | 2023-10-27 | 深圳市信力坚环保科技有限公司 | Sewage treatment detection method |
CN115078677A (en) * | 2022-07-22 | 2022-09-20 | 江苏建深环境科技有限公司 | Monitoring device for water pollution treatment box |
CN115078677B (en) * | 2022-07-22 | 2022-11-08 | 江苏建深环境科技有限公司 | Monitoring device for water pollution treatment box |
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