CN113552310A

CN113552310A - Online automatic monitoring system for water quality of wastewater discharge port

Info

Publication number: CN113552310A
Application number: CN202111090988.1A
Authority: CN
Inventors: 邬金丽
Original assignee: Hai'an Jiachen Environmental Technology Co ltd
Current assignee: Hai'an Jiachen Environmental Technology Co ltd
Priority date: 2021-09-17
Filing date: 2021-09-17
Publication date: 2021-10-26
Anticipated expiration: 2041-09-17
Also published as: CN113552310B

Abstract

The invention discloses an online automatic monitoring system for water quality at a wastewater discharge port, which comprises a shell, wherein a pipeline cavity is arranged in the shell, a wastewater pipe is fixedly arranged on the inner wall of the pipeline cavity, a wastewater cavity is arranged in the wastewater pipe, a supporting shaft is fixedly arranged on the bottom wall of the wastewater cavity, a separating shaft is rotatably arranged on the front side surface of the supporting shaft, a separating plate is fixedly arranged on the periphery of the separating shaft, four rotationally symmetrical separating cavities are arranged on the periphery of the separating plate, a sampling cavity is arranged on the left wall of the pipeline cavity, a blocking plate is slidably arranged in the sampling cavity, a collecting box is fixedly arranged in the right side surface of the pipeline cavity, a weighing pipe is fixedly arranged in the bottom surface of the shell, and a metal cavity is arranged on the left wall of the pipeline cavity. The monitoring station can master the data information in the wastewater at any time.

Description

Online automatic monitoring system for water quality of wastewater discharge port

Technical Field

The invention relates to the technical field of water quality monitoring, in particular to an online automatic monitoring system for the water quality of a wastewater discharge port.

Background

The industrial wastewater comprises production wastewater and production sewage, and refers to wastewater and waste liquid generated in the industrial production process, the wastewater contains heavy metals, suspended matters and other substances, and is directly discharged into a river without being monitored and treated, so that the pollution is extremely large.

Disclosure of Invention

The invention aims to provide an online automatic monitoring system for the water quality of a wastewater discharge port, which is used for overcoming the defects in the prior art.

The online automatic water quality monitoring system for the wastewater discharge port comprises a shell, wherein a pipeline cavity is formed in the shell, a wastewater pipe is fixedly arranged on the inner wall of the pipeline cavity, a wastewater cavity is formed in the wastewater pipe, a support shaft is fixedly arranged on the bottom wall of the wastewater cavity, and a separation shaft is rotatably arranged on the front side surface of the support shaft;

the periphery of the partition shaft is fixedly provided with a partition plate, and the periphery of the partition plate is provided with four rotationally symmetrical partition cavities;

a sampling cavity is formed in the left wall of the pipeline cavity, a barrier plate is arranged in the sampling cavity in a sliding mode, two limiting plates which are bilaterally symmetrical are fixedly arranged on the front side face of the barrier plate, a sampling box is arranged on the front side face of the barrier plate in a sliding mode, and one faces, close to each other, of the two limiting plates can be abutted to the outer peripheral face of the barrier plate;

a sucker cavity is formed in the top wall of the sampling cavity, a sliding plate is arranged in the sucker cavity in a sliding mode, a sucker is fixedly arranged on the bottom surface of the sliding plate, a detection cavity is formed in the rear wall of the sucker cavity, teeth are arranged on the bottom wall of the detection cavity, a detection box is arranged in the detection cavity in a sliding mode and can detect the chemical oxygen demand value of the wastewater;

a collecting box is fixedly arranged in the right side face of the pipeline cavity, a collecting cavity is formed in the collecting box, a weighing pipe is fixedly arranged in the bottom face of the shell, the top end port of the weighing pipe is communicated with the bottom wall of the collecting cavity, a weighing cavity is formed in the weighing pipe, a filter plate is arranged in the weighing cavity in a sliding mode, and the filter plate can filter the wastewater;

the pipeline cavity left wall is provided with a metal cavity, the metal cavity is located the downside of the sampling cavity, the metal cavity rear wall is provided with a rotating shaft in a rotating mode, six rotating plates with six rotational symmetries are fixedly arranged on the periphery of the rotating shaft, and a detector is fixedly arranged at one end, away from each other, of each rotating plate.

Further, a sampling port is formed in the left wall of the wastewater cavity, a right port of the sampling port can be communicated with the separation cavity, a left port of the sampling port is communicated with the sampling cavity, a sliding block is arranged in the sampling cavity in a sliding mode, a sampling rod is fixedly arranged on the right side face of the sliding block, the right end of the sampling rod is fixed to the left side face of the limiting plate on the right side, a sliding block shaft is arranged in the bottom face of the sliding block in a rotating mode, a sliding block gear is fixedly arranged on the periphery of the sliding block shaft and meshed with the bottom wall of the sampling cavity, a sliding motor is fixedly arranged in the sliding block and is in power connection with the sliding block shaft, and the sliding motor is opened to enable the sliding block gear to rotate.

Further, the sampling case internal rotation is equipped with the revolving door axle, the fixed revolving door that is equipped with in the revolving door axle periphery, the sampling case internal fixation is equipped with the revolving door motor, the revolving door motor with revolving door axle power is connected, opens the revolving door motor, makes the revolving door axle with the revolving door rotates.

Furthermore, a water outlet cavity is formed in the bottom surface of the sampling box, a water outlet shaft is arranged on the rear wall of the water outlet cavity in a rotating mode, a water outlet door is fixedly arranged on the periphery of the water outlet shaft, a control motor is fixedly arranged in the rear wall of the water outlet cavity, the control motor is in power connection with the water outlet shaft, and the control motor is started to enable the water outlet shaft and the water outlet door to rotate.

Furthermore, the sliding plate is internally and fixedly provided with two bilateral symmetry material taking motors which are respectively in power connection with the sucker shafts at the same side, and the material taking motors are started to enable the sucker gears to rotate.

Furthermore, the bottom surface of the detection box is provided with a detection shaft in a rotating manner, a detection gear is fixedly arranged on the periphery of the detection shaft, the detection gear is meshed with the bottom wall of the detection cavity, a detection box motor is fixedly arranged in the bottom surface of the detection box, the detection box motor is in power connection with the detection shaft, and the detection box motor is started to enable the detection gear to rotate.

Further, a drying plate is fixedly arranged on the rear wall of the weighing cavity, a drying motor is fixedly arranged in the rear wall of the weighing cavity, the drying motor is in power connection with the drying plate, a weighing plate is fixedly arranged on the top surface of the drying plate, two bilateral symmetric springs are fixedly arranged on the top surface of the weighing plate, the top ends of the two springs are fixed to the bottom surface of the filter plate, when the wastewater flows through the filter plate, suspended matters in the wastewater are reserved on the top surface of the filter plate, and the drying motor is started to heat the drying plate.

Furthermore, a collection port is formed in the right wall of the wastewater cavity, a left port of the collection port can be communicated with the separation cavity, a right port of the collection port can be communicated with the collection cavity, a leakage-proof shaft is arranged on the rear wall of the collection cavity in a rotating mode, a leakage-proof rod is fixedly arranged on the periphery of the leakage-proof shaft, a discharge motor is fixedly arranged in the rear wall of the leakage-proof plate, the discharge motor is in power connection with the leakage-proof shaft, and the discharge motor is started to enable the leakage-proof shaft and the leakage-proof rod to rotate.

Furthermore, a leakage-proof plate is arranged in the collecting port in a sliding mode, the right side face of the leakage-proof plate is fixed with the left end of the leakage-proof rod, and the left side face of the leakage-proof plate can be attached to the inner wall of the collecting cavity.

Furthermore, a communication port is formed in the left wall of the waste water cavity, the right port of the communication port can be communicated with the separation cavity, the left port of the communication port is communicated with the metal cavity, when the waste water flows downwards to pass through the metal cavity, the waste water enables the rotating shaft and the rotating plate to rotate, and six detectors start to detect the heavy metal content of the waste water.

Furthermore, the shell internal fixation is equipped with the data board, the data board can be collected the chemical oxygen demand data value that the detection case detected, the weight value that the check weighing board weighed and the heavy metal content value that the detector detected, just the data board can transmit the numerical information who collects for the monitoring station.

Furthermore, the shell right flank is gone up to rotate and is equipped with two connecting axles of longitudinal symmetry, set up two longitudinal symmetry's connection chamber on the shell left surface, the connecting axle can insert connect the intracavity, just the connecting axle outer peripheral face can with connect intracavity wall threaded connection, the shell right flank internal fixation is equipped with two longitudinal symmetry's connection motor, two connect the motor respectively with the homonymy the connecting axle power is connected, opens connect the motor, makes the connecting axle rotates.

Furthermore, a switching motor is fixedly arranged in the front side face of the supporting shaft and is in power connection with the partition shaft, and the switching motor is started to enable the partition shaft and the partition plate to rotate.

The invention has the beneficial effects that: the on-line automatic monitoring system for the water quality at the wastewater discharge port is provided with the sampling box, so that the sampling can be carried out at any time and the chemical oxygen demand data value can be detected automatically, the filtering plate and the drying device are arranged, the content of suspended matters in the wastewater can be measured at any time, the heavy metal detection device is arranged, the content of heavy metals in the wastewater can be detected accurately in real time, the data can be collected in a centralized manner, the collected data can be transmitted to the monitoring station in real time, the monitoring station can master the data information in the wastewater at any time, and four different wastewater sources can be detected, so that the detection efficiency and the utilization rate of the detection device are improved.

Drawings

FIG. 1 is a schematic view of the external appearance of an on-line automatic monitoring system for water quality at a wastewater discharge port of the present invention;

FIG. 2 is a schematic cross-sectional view of an on-line automatic monitoring system for water quality at a wastewater discharge port according to the present invention;

FIG. 3 is a partial schematic view of FIG. 2 of the present invention;

FIG. 4 is a schematic side view taken at A-A of FIG. 2 in accordance with the present invention;

fig. 5 is a partially enlarged schematic view of the invention at B in fig. 2.

In the figure:

10. a housing; 11. a conduit cavity; 12. a waste pipe; 13. a waste water chamber; 14. a partition plate; 15. a separation chamber; 16. a support shaft; 17. a partition shaft; 18. a data board; 19. a connecting shaft; 20. a connecting cavity; 21. a sampling cavity; 22. a slider; 23. a slider shaft; 24. a slider gear; 25. a sampling rod; 26. a blocking plate; 27. a limiting plate; 28. a sampling box; 29. a rotating door; 30. a door rotating shaft; 31. a water outlet cavity; 32. a water outlet door; 33. a water outlet shaft; 34. a sucker cavity; 35. a detection chamber; 36. a detection box; 37. detecting a shaft; 38. detecting the gear; 39. a sliding plate; 40. a chuck shaft; 41. a sucker gear; 42. a suction cup; 43. a sampling port; 45. a metal cavity; 44. a communication port; 46. a rotating shaft; 47. a rotating plate; 48. a detector; 49. a collection port; 50. a leak-proof plate; 51. a collection box; 52. a collection chamber; 53. a leakage-proof rod; 54. a leakage-proof shaft; 57. a spring; 56. a filter plate; 55. a weighing tube; 58. measuring a weight plate; 59. drying the plate; 60. and a weighing cavity.

Detailed Description

In order to make the objects and advantages of the present invention more apparent, the following detailed description of the present invention is given in conjunction with the examples, it should be understood that the following text is only used to describe one kind of automatic online monitoring system for waste water discharge outlet water quality or several specific embodiments of the present invention, and does not strictly limit the scope of the protection specifically claimed by the present invention, as used herein, the terms up, down, left and right are not limited to their strict geometric definitions, but include tolerances for reasonable and inconsistent machining or human error, and the following detailed description of the specific features of the automatic online monitoring system for waste water discharge outlet water quality is given in detail:

referring to the attached drawings, the online automatic monitoring system for the water quality at the wastewater discharge port according to the embodiment of the invention comprises a shell 10, wherein a pipeline cavity 11 is formed in the shell 10, a wastewater pipe 12 is fixedly arranged on the inner wall of the pipeline cavity 11, wastewater is discharged through the wastewater pipe 12, a wastewater cavity 13 is formed in the wastewater pipe 12, a support shaft 16 is fixedly arranged on the bottom wall of the wastewater cavity 13, and a separation shaft 17 is rotatably arranged on the front side surface of the support shaft 16;

the periphery of the partition shaft 17 is fixedly provided with a partition plate 14, the periphery of the partition plate 14 is provided with four rotationally symmetrical partition cavities 15, and different waste water can flow in the four partition cavities 15 respectively;

a sampling cavity 21 is formed in the left wall of the pipeline cavity 11, a blocking plate 26 is slidably arranged in the sampling cavity 21, two bilaterally symmetrical limiting plates 27 are fixedly arranged on the front side face of the blocking plate 26, a sampling box 28 is slidably arranged on the front side face of the blocking plate 26, one mutually close face of each limiting plate 27 can be abutted against the outer peripheral face of the blocking plate 26, and the blocking plate 26 can be prevented from rolling leftwards and rightwards through the two limiting plates 27;

a sucker cavity 34 is formed in the top wall of the sampling cavity 21, a sliding plate 39 is arranged in the sucker cavity 34 in a sliding mode, a sucker 42 is fixedly arranged on the bottom surface of the sliding plate 39, the bottom surface of the sucker 42 can be abutted to the top surface of the sampling box 28, the sucker 42 can suck the sampling box 28, a detection cavity 35 is formed in the rear wall of the sucker cavity 34, teeth are arranged on the bottom wall of the detection cavity 35, a detection box 36 is arranged in the detection cavity 35 in a sliding mode, and the detection box 36 can detect the chemical oxygen demand value of wastewater;

a collecting box 51 is fixedly arranged in the right side surface of the pipeline cavity 11, a collecting cavity 52 is formed in the collecting box 51, a weighing pipe 55 is fixedly arranged in the bottom surface of the shell 10, the top end port of the weighing pipe 55 is communicated with the bottom wall of the collecting cavity 52, a weighing cavity 60 is formed in the weighing pipe 55, a filter plate 56 is arranged in the weighing cavity 60 in a sliding mode, and the filter plate 56 can filter the wastewater;

seted up metal cavity 45 on the 11 left walls in pipeline chamber, metal cavity 45 is located the downside in sample chamber 21, it is equipped with axis of rotation 46 to rotate on the 45 back walls in metal cavity, the fixed rotor plate 47 that is equipped with six rotational symmetry in the axis of rotation 46 periphery, six all fixed being equipped with detector 48, six on the one end that rotor plate 47 kept away from each other detector 48 homoenergetic detects the heavy metal content of waste water.

Preferably, a sampling port 43 is formed on the left wall of the waste water cavity 13, the right port of the sampling port 43 can be communicated with the separation cavity 15, the left port of the sampling port 43 is communicated with the sampling cavity 21, a sliding block 22 is arranged in the sampling cavity 21 in a sliding way, a sampling rod 25 is fixedly arranged on the right side surface of the sliding block 22, the right end of the sampling rod 25 is fixed with the left side surface of the limiting plate 27 on the right side, the sampling box 28 can be slid into the compartment 15 from the inside of the sampling cavity 21 to the right by means of the sampling rod 25, a slider shaft 23 is rotationally arranged on the bottom surface of the slider 22, a slider gear 24 is fixedly arranged on the periphery of the slider shaft 23, the sliding block gear 24 is meshed with the bottom wall of the sampling cavity 21, a sliding motor is fixedly arranged in the sliding block 22, the sliding motor is in power connection with the sliding block shaft 23, and the sliding motor is started to enable the sliding block gear 24 to rotate.

Preferably, a rotating door shaft 30 is arranged in the sampling box 28 in a rotating mode, a rotating door 29 is fixedly arranged on the periphery of the rotating door shaft 30, the rotating door 29 can prevent the wastewater collected in the sampling box 28 from flowing out, a rotating door motor is fixedly arranged in the sampling box 28, the rotating door motor is in power connection with the rotating door shaft 30, and the rotating door motor is started to enable the rotating door shaft 30 and the rotating door 29 to rotate.

Preferably, sample case 28 has been seted up on the bottom surface and has been gone out water cavity 31, waste water in the sample case 28 can pass through go out water cavity 31 and flow out downwards, it is equipped with out water axle 33 to rotate on the wall behind water cavity 31, it is equipped with out water door 32 to go out to fix in the water axle 33 periphery, it is equipped with control motor to go out water cavity 31 back wall internal fixation, control motor with go out water axle 33 power connection, open control motor makes go out water axle 33 with it rotates to go out water door 32.

Preferably, the sliding plate 39 is rotatably provided with two bilateral symmetric suction cup shafts 40, two suction cup gears 41 are fixedly arranged on the peripheries of the two suction cup shafts 40, the left wall and the right wall of the suction cup cavity 34 are respectively engaged with the suction cup gears 41 on the same side, the sliding plate 39 can slide up and down in the suction cup cavity 34 through the two suction cup gears 41, the sliding plate 39 is internally and fixedly provided with two bilateral symmetric material taking motors, the two material taking motors are respectively in power connection with the suction cup shafts 40 on the same side, and the material taking motors are turned on to enable the suction cup gears 41 to rotate.

Preferably, the bottom surface internal rotation of detection case 36 is equipped with detection shaft 37, the fixed detection gear 38 that is equipped with in detection shaft 37 periphery, detect gear 38 with detect 35 diapire meshes in the chamber, detection case 36 passes through detection gear 38 can slide around in the detection chamber 35, just detection case 36 front end can be followed it slides in the detection chamber 35 in the sucking disc chamber 34, detection case 36 bottom surface internal fixation is equipped with and examines the case motor, examine the case motor with detection shaft 37 power is connected, opens examine the case motor, make detection gear 38 rotates.

Preferably, a drying plate 59 is fixedly arranged on the rear wall of the weighing cavity 60, the drying plate 59 can be heated to generate heat, so that water on the filter plate 56 can be evaporated, a drying motor is fixedly arranged in the rear wall of the weighing cavity 60, the drying motor is in power connection with the drying plate 59, a weight measuring plate 58 is fixedly arranged on the top surface of the drying plate 59, the weight measuring plate 58 can weigh the weight of solids on the top surface of the filter plate 56, two bilateral-symmetrical springs 57 are fixedly arranged on the top surface of the weight measuring plate 58, the top ends of the two springs 57 are fixed with the bottom surface of the filter plate 56, when the wastewater flows through the filter plate 56, suspended matters in the wastewater are reserved on the top surface of the filter plate 56, and the drying motor is started to heat the drying plate 59.

Preferably, a collection port 49 is formed in the right wall of the wastewater cavity 13, the left port of the collection port 49 can be communicated with the separation cavity 15, the right port of the collection port 49 can be communicated with the collection cavity 52, wastewater can flow into the collection cavity 52 from the separation cavity 15 through the collection port 49, a leakage-proof shaft 54 is rotatably arranged on the rear wall of the collection cavity 52, a leakage-proof rod 53 is fixedly arranged on the periphery of the leakage-proof shaft 54, a discharge motor is fixedly arranged in the rear wall of the leakage-proof plate 50, and the discharge motor is in power connection with the leakage-proof shaft 54 and is started to enable the leakage-proof shaft 54 and the leakage-proof rod 53 to rotate.

Preferably, a leakage-proof plate 50 is arranged in the collection port 49 in a sliding manner, the right side face of the leakage-proof plate 50 is fixed to the left end of the leakage-proof rod 53, the left side face of the leakage-proof plate 50 can be attached to the inner wall of the collection cavity 52, the leakage-proof plate 50 can prevent the wastewater from flowing into the collection cavity 52 from the collection port 49, and the leakage-proof plate 50 can prevent the wastewater from flowing into the weighing cavity 60 from the collection cavity 52.

Preferably, a communication port 44 is formed in the left wall of the wastewater cavity 13, the right port of the communication port 44 can be communicated with the separation cavity 15, the left port of the communication port 44 is communicated with the metal cavity 45, the wastewater can flow into the metal cavity 45 from the separation cavity 15 through the communication port 44, when the wastewater flows downward through the metal cavity 45, the wastewater rotates the rotating shaft 46 and the rotating plate 47, and the six detectors 48 start to detect the heavy metal content of the wastewater.

Preferably, a data board 18 is fixedly arranged in the housing 10, the data board 18 can collect the chemical oxygen demand data value detected by the detection box 36, the weight value weighed by the weight measuring board 58 and the heavy metal content value detected by the detector 48, and the data board 18 can transmit the collected numerical information to a monitoring station.

Preferably, the connecting axle 19 that is equipped with two longitudinal symmetries rotates on the shell 10 right flank, set up two longitudinal symmetries's connection chamber 20 on the shell 10 left surface, connecting axle 19 can insert connect in the chamber 20, just 19 outer peripheral faces of connecting axle can with connect 20 inner wall threaded connection in chamber, two the shell 10 can pass through connecting axle 19 with connect chamber 20 composite mounting together, shell 10 right flank internal fixation is equipped with two longitudinal symmetries's connection motor, two connect the motor respectively with the homonymy 19 power connection of connecting axle, opens connect the motor, make connecting axle 19 rotates.

Preferably, a switching motor is fixedly arranged in the front side surface of the supporting shaft 16, the switching motor is in power connection with the separating shaft 17, and the switching motor is started to enable the separating shaft 17 and the separating plate 14 to rotate.

The invention relates to an online automatic monitoring system for the water quality of a wastewater discharge port, which comprises the following working procedures:

and (3) detecting chemical oxygen demand: starting the switching motor to rotate the partition shaft 17 and the partition plate 14 until one of the partition chambers 15 is communicated with the right port of the sampling port 43;

turning on the sliding motor to rotate the slider gear 24 and slide the sliding block 22 to the right, so that the blocking plate 26 and the sampling box 28 slide into the separation cavity 15 from the sampling cavity 21;

turning on the swing door motor to rotate the swing door shaft 30 and the swing door 29 ninety degrees to allow the wastewater to flow into the sampling tank 28, turning on the swing door motor again to rotate the swing door shaft 30 and the swing door 29 ninety degrees again to allow the sampling tank 28 to complete sampling of the wastewater;

starting the sliding motor again to enable the sampling box 28 to slide into the sampling cavity 21 leftwards until the sampling box 28 is aligned with the bottom port of the sucker cavity 34 up and down;

turning on the material taking motor to rotate the suction disc gear 41, so that the sliding plate 39 and the suction disc 42 slide downwards until the bottom surface of the suction disc 42 abuts against the bottom surface of the sampling box 28, so that the suction disc 42 sucks the sampling box 28, turning on the material taking motor again to slide the suction disc 42 upwards, so that the sampling box 28 slides upwards into the suction disc cavity 34 along with the suction disc 42 until the top surface of the sliding plate 39 abuts against the top wall of the suction disc cavity 34;

starting the box detection motor, enabling the detection gear 38 to rotate, enabling the detection box 36 to slide forwards, and enabling the front end of the detection box 36 to slide into the suction disc cavity 34 until the top port of the detection box 36 is vertically aligned with the bottom port of the water outlet cavity 31;

and starting the control motor to rotate the water outlet shaft 33 and the water outlet door 32 ninety degrees, so that the wastewater in the sampling box 28 flows into the detection box 36 through the water outlet cavity 31, and the detection box 36 can detect the COD data value in the wastewater.

Detecting suspended matters: starting the discharging motor to enable the leakage-proof shaft 54 and the leakage-proof rod 53 to rotate, so that the leakage-proof plate 50 rotates along with the leakage-proof rod 53 until the leakage-proof plate 50 seals the top end opening of the weighing tube 55;

starting the switching motor to rotate the partition shaft 17 and the partition plate 14 until one of the partition chambers 15 is communicated with the left port of the collection port 49, and the wastewater in the partition chamber 15 flows into the collection chamber 52;

starting the switching motor again to ensure that any one of the separation cavities 15 is not communicated with the collecting port 49, then starting the discharging motor to ensure that the leakage-proof plate 50 rotates until the leakage-proof plate 50 seals the left opening of the collecting cavity 52, and the wastewater in the collecting cavity 52 flows downwards into the weighing cavity 60;

when the wastewater flows through the filter plate 56, the filter plate 56 makes suspended matters in the wastewater stay on the top surface of the filter plate 56, then the drying motor is started to heat the drying plate 59, the drying plate 59 can dry the water on the filter plate 56, and the weight measuring plate 58 can weigh the suspended matters on the filter plate 56.

And (3) heavy metal detection: and starting the switching motor to enable the separation shaft 17 and the separation plate 14 to rotate until one separation cavity 15 is communicated with the right end port of the communication port 44, enabling the wastewater in the separation cavity 15 to flow into the metal cavity 45, enabling the rotating shaft 46 and the rotating plate 47 to rotate by the wastewater, and enabling six detectors 48 to continuously detect the heavy metal content of the wastewater.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims

1. The utility model provides an online automatic monitoring system of wastewater discharge port quality of water, includes the shell, its characterized in that: a pipeline cavity is formed in the shell, a waste water pipe is fixedly arranged on the inner wall of the pipeline cavity, a waste water cavity is formed in the waste water pipe, a supporting shaft is fixedly arranged on the bottom wall of the waste water cavity, and a separating shaft is rotatably arranged on the front side surface of the supporting shaft;

a sucker cavity is formed in the top wall of the sampling cavity, a sliding plate is arranged in the sucker cavity in a sliding mode, a sucker is fixedly arranged on the bottom surface of the sliding plate, a detection cavity is formed in the rear wall of the sucker cavity, a detection box is arranged in the detection cavity in a sliding mode, and teeth are arranged on the bottom wall of the detection cavity;

a collecting box is fixedly arranged in the right side face of the pipeline cavity, a collecting cavity is formed in the collecting box, a weighing pipe is fixedly arranged in the bottom face of the shell, the top end port of the weighing pipe is communicated with the bottom wall of the collecting cavity, a weighing cavity is formed in the weighing pipe, and a filter plate is arranged in the weighing cavity in a sliding mode;

2. The online automatic monitoring system for the water quality of the wastewater discharge port according to claim 1, characterized in that: the utility model discloses a take out the sample, including waste water chamber, sampling opening's right-hand member mouth, sliding block, sampling opening's left port with the chamber intercommunication of taking a sample, the intracavity that takes a sample slides and is equipped with the sliding block, the fixed sampling rod that is equipped with on the sliding block right flank, the sampling rod right-hand member is fixed with the right side the left surface of limiting plate, sliding block bottom surface internal rotation is equipped with the slider axle, the fixed slider gear that is equipped with in the slider axle periphery, the slider gear with the meshing of sample chamber bottom wall.

3. The online automatic monitoring system for the water quality of the wastewater discharge port according to claim 1, characterized in that: the sampling box internal rotation is equipped with the pivot, the fixed revolving door that is equipped with in the pivot periphery, set up out the water cavity on the sampling box bottom surface, it is equipped with the water axle to rotate on the water cavity back wall, it is equipped with out the water door to go out to fix in the water axle periphery.

4. The online automatic monitoring system for the water quality of the wastewater discharge port according to claim 1, characterized in that: the detection box is characterized in that two suction disc shafts which are bilaterally symmetrical are arranged in the sliding plate in a rotating mode, suction disc gears are fixedly arranged on the peripheries of the two suction disc shafts, the left wall and the right wall of a suction disc cavity are respectively meshed with the suction disc gears on the same side, a detection shaft is arranged in the bottom surface of the detection box in a rotating mode, a detection gear is fixedly arranged on the periphery of the detection shaft, and the detection gear is meshed with the bottom wall of the detection cavity.

5. The online automatic monitoring system for the water quality of the wastewater discharge port according to claim 2, characterized in that: the weighing device is characterized in that a drying plate is fixedly arranged on the rear wall of the weighing cavity, a weight measuring plate is fixedly arranged on the top surface of the drying plate, two bilateral symmetric springs are fixedly arranged on the top surface of the weight measuring plate, and the top ends of the two springs are fixed with the bottom surface of the filter plate.

6. The online automatic monitoring system for the water quality of the wastewater discharge port according to claim 2, characterized in that: the waste water collecting device is characterized in that a collecting port is formed in the right wall of the waste water cavity, a left port of the collecting port can be communicated with the separation cavity, a right port of the collecting port can be communicated with the collecting cavity, a leakage-proof shaft is rotatably arranged on the rear wall of the collecting cavity, and a leakage-proof rod is fixedly arranged on the periphery of the leakage-proof shaft.

7. The online automatic monitoring system for the water quality of the wastewater discharge port according to claim 6, characterized in that: the inner side of the collecting cavity is provided with a leakage-proof plate in a sliding mode, the right side face of the leakage-proof plate is fixed with the left end of the leakage-proof rod, and the left side face of the leakage-proof plate can be attached to the inner wall of the collecting cavity.

8. The on-line automatic monitoring system for the water quality of the wastewater discharge port according to claim 5, characterized in that: the waste water cavity comprises a waste water cavity, a detection box and a detection instrument, wherein a communication port is formed in the left wall of the waste water cavity, the right port of the communication port can be communicated with a separation cavity, the left port of the communication port is communicated with a metal cavity, a data board is fixedly arranged in a shell, the data board can collect a chemical oxygen demand data value detected by the detection box, a weight value weighed by the weighing board and a heavy metal content value detected by the detection instrument, and the data board can transmit the collected numerical information to the monitoring station.

9. The online automatic monitoring system for the water quality of the wastewater discharge port according to claim 2, characterized in that: the connecting shaft is characterized in that two connecting shafts which are symmetrical up and down are rotatably arranged on the right side face of the shell, two connecting cavities which are symmetrical up and down are formed in the left side face of the shell, the connecting shafts can be inserted into the connecting cavities, and the outer peripheral faces of the connecting shafts can be in threaded connection with the inner walls of the connecting cavities.