CN116735823A - Sewage monitoring device for rural environment management - Google Patents

Abstract

The invention discloses a sewage monitoring device for rural environment management, and relates to the technical field of sewage management; the invention comprises a floating component, wherein the floating component comprises a floating plate, a fixed component is arranged in the tail end of the floating plate, a regulating component is arranged in the middle of the floating plate, the regulating component comprises a rotating disc movably hinged to the center of the top of the floating plate, one end of the top of the rotating disc is fixedly connected with a rope collecting component, the other end of the top of the regulating component is provided with a lifting control component, after the driving motor operates, the output end of the regulating component drives the driving disc to rotate, and the driving disc rotates under the action force of mutual engagement between gear patterns on the side part of the driving disc and gear patterns on the side part of the rotating disc, so that the rotating disc reversely rotates, and the position of a lifting rod and a probe rope required to be collected and monitored is regulated, and the flexibility of the regulating component for sewage sampling is further improved.

Description

Sewage monitoring device for rural environment management

Technical Field

The invention belongs to the technical field of sewage management, and particularly relates to a sewage monitoring device for rural environment management.

Background

Along with the continuous development of the urban process, more and more factories are raised, and the transfer of the factories from cities to rural areas not only reduces the labor cost of the factories and brings employment posts to rural population, but also threatens the rural environment, a large amount of waste sewage can be generated in the production process of the factories, and the sewage is directly discharged into lakes and rivers in a sewage treatment mode, so that the rural water quality environment is greatly influenced, and therefore, the sewage monitoring device for rural environment management needs to be provided;

at present, the rural environment management of present stage is with sewage monitoring devices, mostly adopts with the collector installation on the steel pipe, inserts the aquatic with the steel pipe after, gathers the back with the quality of water through the collector, takes out the quality of water of gathering after, and rethread check out test set detects the quality of water, and its operation is comparatively loaded down with trivial details, can't confirm the position that the degree of depth of steel pipe inserted in aquatic was gathered simultaneously, leads to detecting index inaccurate, has certain defect.

Accordingly, there is a need to provide a sewage monitoring device for rural environmental management, which aims to solve the above problems.

Disclosure of Invention

The invention aims to provide a sewage monitoring device for rural environment management, which solves the problems that the existing sewage monitoring device for rural environment management adopts a mode of detection after manual collection and cannot control the collected depth, so that the detection index is inaccurate.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to a sewage monitoring device for rural environment management, which comprises a buoy assembly, wherein the buoy assembly comprises a buoy plate, a fixing assembly is arranged in the tail end of the buoy plate, a regulating assembly is arranged in the middle of the buoy plate, the regulating assembly comprises a rotating disc movably hinged to the center of the top of the buoy plate, one end of the top of the rotating disc is fixedly connected with a rope collecting assembly, and the other end of the top of the regulating assembly is provided with a lifting control assembly.

According to the preferable scheme, the side part of the floating plate is fixedly connected with the air charging ring, the side part of the air charging ring is provided with the air transmission interface, and the air transmission interface is in threaded connection with the sealing cover.

According to the preferred scheme, the supporting rods are fixedly connected to four direction angles at the top of the floating plate, the equipment mounting plate is fixedly connected to the top of the supporting rods, the illuminating lamp is fixedly connected to the top of the front end of the equipment mounting plate, meanwhile, the steering mechanism is arranged at the top of the equipment mounting plate and far away from the center position and between the front end, the monitoring probe is fixedly connected to the top of the steering mechanism, the water quality detector is fixedly connected to the top of the equipment mounting plate and far away from the tail end and the center position, the hinge groove is formed in the tail end of the top of the equipment mounting plate, and the solar plate is movably hinged in the hinge groove.

According to the preferred scheme, the fixing component comprises a rope winding box fixedly connected with the tail end of the floating plate, two ends of the tail end of the rope winding box are movably hinged with limiting side plates, the inner side faces opposite to the limiting side plates are fixedly connected with winding rods, traction ropes are movably sleeved on the side parts of the winding rods, meanwhile, transmission gears are fixedly connected with the outer side faces of the limiting side plates at the right end, transmission tracks are movably sleeved on the side parts of the transmission gears, driving gears are movably sleeved on the inner side faces of the front ends of the transmission tracks, driving motors are arranged in the tail ends of the floating plates, and the output ends of the driving motors are fixedly connected with the center positions of the side parts of the driving gears.

According to the preferred scheme, the top of the floating plate and the side part far away from the rotating disc are fixedly connected with the transmission motor, the output end of the transmission motor is fixedly connected with the transmission disc, and meanwhile, the transmission disc and the side part of the rotating disc are both provided with gear patterns which are meshed with each other.

According to the preferred scheme, the rope collecting assembly comprises a rope collecting box fixedly connected with one end of the top of a rotating disc, track plates are fixedly connected to two ends of the inside of the rope collecting box, track grooves are formed in the inner side faces opposite to the track plates, tension springs are fixedly connected to the tail ends of the inside of the track grooves, moving blocks are fixedly connected to the front ends of the tension springs, limiting rollers are movably hinged to the inner side faces opposite to the moving blocks, probe ropes are movably sleeved on the side portions of the limiting rollers, sewage detection probes are mounted at the front ends of the probe ropes, hinge buttons are arranged at the front ends of the inner side faces opposite to the track plates, rotating rollers are movably hinged to the inner side faces opposite to the hinge buttons, and conducting motors are fixedly connected to the outer side faces of the front ends of the left track plates, and output ends of the conducting motors penetrate through the inner sides of the track plates and are fixedly connected to one ends of the rotating rollers.

According to the preferred scheme, the lifting control assembly comprises a stabilizing groove formed in the other end of the top of the rotating disc, a micro motor is fixedly connected to the side portion of the stabilizing groove, meanwhile, a rotating gear is movably hinged to the tail end inside the stabilizing groove, and the output end of the micro motor is fixedly connected to the center position of the side portion of the rotating gear.

According to the preferred scheme, the lifting rod is movably sleeved in the stabilizing groove, and the gear patterns are arranged on the side parts of the lifting rod and are meshed with the gear patterns on the side parts of the rotating gears.

According to the preferred scheme, stable sliding grooves are formed in two sides of the inside of the lifting rod and between the middle part and the tail end of the lifting rod, a spring rod is fixedly connected to the front end of the inside of the stable sliding grooves, meanwhile, a sliding block is movably connected to the inside of the stable sliding grooves, the front end of the spring rod is fixedly connected to the tail end of the sliding block, and an auxiliary roller is movably hinged to the inner side surface of the sliding block opposite to the front end of the spring rod.

According to the preferred scheme, the middle parts of the two sides of the inside of the lifting rod are movably hinged with the limiting roller, the two ends of the limiting roller are fixedly connected with the transmission toothed sheets, the inside of the lifting rod, which is far away from the middle part and the tail end, is fixedly connected with the gear motor, the output end of the gear motor is fixedly connected with the driving toothed sheet, and meanwhile, the side parts of the driving toothed sheet and the transmission toothed sheet are movably sleeved with the toothed sheet crawler belt.

The invention has the following beneficial effects:

1. according to the invention, through the design of the rope collecting assembly and the lifting control assembly, under the action force of gear engagement between the gear lines on the side part of the rotating gear and the corresponding surface of the lifting rod, the rotating gear rotates clockwise, so that the lifting rod moves downwards gradually until reaching the required collection depth, the operation is stopped, the water flow in water penetrates into the lifting rod, and the probe rope sleeved on the side part of the rotating roller is conveyed to the bottom end of the lifting rod gradually until reaching the bottom end of the lifting rod by controlling the synchronous operation of the conducting motor and the gear motor, so that the water flow is collected, the accuracy of sewage collection at different depths can be ensured, and the problem that the probe rope swings along with the flow direction of the water and cannot be vertically downwards reached to the designated depth to collect the water flow is avoided.

2. According to the invention, through the design of the regulating and controlling assembly, the rope collecting assembly and the lifting and controlling assembly, after the driving motor operates, the output end of the rope collecting assembly drives the driving disc to rotate, and the driving disc rotates under the action force of mutual engagement between the gear patterns on the side part of the driving disc and the gear patterns on the side part of the driving disc, so that the driving disc rotates reversely, thereby realizing the adjustment of the positions of the lifting rod and the probe rope required to be collected and monitored, and further improving the flexibility of the lifting rod and the probe rope on sewage sampling.

3. According to the invention, under the action force of the tension spring expanding and pushing the moving block, the limit roller is close to the rotary roller, and when the conduction motor is electrified and operated, the output end of the conduction motor drives the rotary roller to rotate, so that the probe rope is retracted and extended in a clamped state, and the retraction and extension stability of the probe rope is improved.

Of course, it is not necessary for any one product to practice the invention to achieve all of the advantages set forth above at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall top structure of the device;

FIG. 2 is a schematic view of the overall structure of the top of the floating plate;

FIG. 3 is a schematic view of the overall structure of the fixing assembly;

FIG. 4 is a schematic view of the limiting roller and the rotating roller;

FIG. 5 is a schematic view of the overall structure of the interior of the track slab;

FIG. 6 is a schematic view of the overall structure of the inside of the stabilizing trough;

FIG. 7 is a schematic view of the overall connection structure of the top of the rotating disc;

fig. 8 is a schematic view of the overall connection structure of the limiting roller and the gear motor.

In the drawings, the list of components represented by the various numbers is as follows:

1. a float assembly; 101. a float plate; 102. an air charging ring; 103. sealing cover; 104. a support rod; 105. an equipment mounting plate; 106. a lighting lamp; 107. a steering mechanism; 108. monitoring a probe; 109. a water quality detector; 110. a hinge groove; 111. a solar panel;

2. a fixing assembly; 201. a rope winding box; 202. limiting side plates; 203. a winding rod; 204. a traction rope; 205. a transmission gear; 206. a drive track; 207. a drive gear; 208. a driving motor;

3. a regulatory component; 301. a drive motor; 302. a drive plate; 303. a rotating disc;

4. a rope collecting component; 401. a rope collecting box; 402. a track plate; 403. a track groove; 404. a tension spring; 405. a moving block; 406. a limit roller; 407. a probe rope; 408. a hinge button; 409. a conduction motor; 410. rotating the drum;

5. a lift control assembly; 501. a stabilizing groove; 502. a micro motor; 503. rotating the gear; 504. a lifting rod; 505. stabilizing the chute; 506. a spring rod; 507. a sliding block; 508. an auxiliary drum; 509. a limiting roller; 510. a driving tooth plate; 511. tooth plate caterpillar band; 512. driving the tooth plate; 513. a gear motor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Examples: referring to fig. 1-8, the sewage monitoring device for rural environment management is shown, the sewage monitoring device comprises a buoy assembly 1, the buoy assembly 1 comprises a buoy plate 101, a fixing assembly 2 is installed in the tail end of the buoy plate 101, a regulating and controlling assembly 3 is installed in the middle of the buoy plate 101, the regulating and controlling assembly 3 comprises a rotating disc 303 movably hinged to the center of the top of the buoy plate 101, a rope collecting assembly 4 is fixedly connected to one end of the top of the rotating disc 303, and a lifting and controlling assembly 5 is installed at the other end of the top of the regulating and controlling assembly 3.

In this embodiment, as shown in fig. 1 and 2, the side portion of the floating plate 101 is fixedly connected with an air charging ring 102, the side portion of the air charging ring 102 is provided with an air delivery interface, and a sealing cover 103 is screwed at the air delivery interface.

Wherein, through the inside transport gas from gas-supply interface department to the charging collar 102, make charging collar 102 inflation to guarantee after float plate 101 is placed in water, play the auxiliary role to float plate 101 at the surface of water, can follow gas-supply interface department many times to the inside of charging collar 102 in the later stage make up gas.

In this embodiment, referring to fig. 1 and 2, the four direction angles at the top of the float plate 101 are all fixedly connected with a support rod 104, the top end of the support rod 104 is fixedly connected with an equipment mounting plate 105, the top of the front end of the equipment mounting plate 105 is fixedly connected with an illuminating lamp 106, meanwhile, the top of the equipment mounting plate 105 is far away from the center position and the front end, a steering mechanism 107 is installed between the center position and the front end, a monitoring probe 108 is fixedly connected to the top of the steering mechanism 107, a water quality detector 109 is fixedly connected to the top of the equipment mounting plate 105 and far away from the tail end and the center position, a hinge groove 110 is formed at the tail end of the top of the equipment mounting plate 105, and a solar panel 111 is movably hinged inside the hinge groove 110.

Wherein, the top of four bracing pieces 104 corresponds the four direction angular positions of fixing in equipment mounting panel 105 bottom, play the effect of supporting equipment mounting panel 105, play simultaneously and separate the effect between equipment mounting panel 105 and the cursory board 101, and light 106 is the LED rectangle lamp, can provide the effect of illuminating the surface of water at night, steering mechanism 107 can control and turn left and right, make the monitoring probe 108 of top installation can monitor peripheral surface of water condition, simultaneously water quality detector 109 can carry out the effect of analysis to the quality of water of gathering, realize adjusting solar panel 111's upper and lower visual angle through the upset solar panel 111 back and forth, place in hinge groove 110 when solar panel 111 level, the visual angle of solar panel 111 is upwards, the sunlight of receiving that can be better.

In this embodiment, as shown in fig. 2 and 3, the fixing assembly 2 includes a rope winding box 201 fixedly connected to the tail end of the float plate 101, two ends inside the rope winding box 201 are movably hinged with a limiting side plate 202, a winding rod 203 is fixedly connected to opposite inner side surfaces of the limiting side plate 202, a traction rope 204 is movably sleeved on a side portion of the winding rod 203, a transmission gear 205 is fixedly connected to an outer side surface of the limiting side plate 202 at the right end, a transmission crawler 206 is movably sleeved on a side portion of the transmission gear 205, a driving gear 207 is movably sleeved on an inner side surface of the front end of the transmission crawler 206, a driving motor 208 is installed inside the tail end of the float plate 101, and an output end of the driving motor 208 is fixedly connected to a center position of the side portion of the driving gear 207.

Wherein, the output end of the driving motor 206 has a bidirectional rotation function, and in the state that the driving motor 206 is electrified, the output end drives the driving gear 207 to rotate, so that the driving crawler 206 drives in the same direction and drives the driving gear 205 to rotate, so as to drive the winding rod 203 to rotate, when the winding rod 203 rotates clockwise or anticlockwise, the winding and unwinding of the traction rope 204 are realized, and meanwhile, the limiting side plates 202 installed at two ends are used for limiting the traction rope 204 to separate from the winding rod 203 in the winding and unwinding process.

In this embodiment, as shown in fig. 2, a transmission motor 301 is fixedly connected to the top of the floating plate 101 and the side portion far away from the rotating disc 303, a transmission disc 302 is fixedly connected to the output end of the transmission motor 301, and gear patterns are disposed on the sides of the transmission disc 302 and the rotating disc 303 and meshed with each other.

Wherein, the output end of the transmission motor 301 has a bidirectional rotation function, when the transmission motor 301 is electrified and operated, the transmission disc 302 is rotated under the state of controlling the rotation of the output end, and at the moment, the rotation disc 303 is reversely rotated under the action force of the mutual engagement between the gear patterns arranged on the side part and the gear patterns on the side part of the rotation disc, so as to realize the regulation and control of the position of the line paid by the probe rope 407.

In this embodiment, as shown in fig. 4 and 5, the rope collecting assembly 4 includes a rope collecting box 401 fixedly connected to one end of the top of the rotating disc 303, a track plate 402 fixedly connected to two ends of the inside of the rope collecting box 401, a track slot 403 formed on the opposite inner side of the track plate 402, a tension spring 404 fixedly connected to the tail end of the inside of the track slot 403, a moving block 405 fixedly connected to the front end of the tension spring 404, a limit roller 406 movably hinged to the opposite inner side of the moving block 405, a probe rope 407 movably sleeved to the side of the limit roller 406, and a sewage detection probe mounted to the front end of the probe rope 407, hinge buttons 408 provided to the front ends of the opposite inner sides of the track plate 402, a rotating roller 410 movably hinged to the opposite inner sides of the hinge buttons 408, a conductive motor 409 fixedly connected to the outer side of the front end of the left track plate 402, and an output end of the conductive motor 409 penetrating through the inside of the track plate 402 and fixedly connected to one end of the rotating roller 410.

The tension spring 404 can realize the function of pushing the moving block 405 forward, so that the limit roller 406 can approach the rotating roller 410, the probe rope 407 is clamped, the output end of the conducting motor 409 has the function of bidirectional rotation, and the output end drives the rotating roller 410 to rotate under the state that the conducting motor 409 is electrified to operate, so that the probe rope 407 is wound and unwound.

In this embodiment, as shown in fig. 5, the lifting control assembly 5 includes a stabilizing slot 501 formed at the other end of the top of the rotating disc 303, a micro motor 502 is fixedly connected to the side of the stabilizing slot 501, and meanwhile, a rotating gear 503 is movably hinged to the tail end inside the stabilizing slot 501, and the output end of the micro motor 502 is fixedly connected to the center of the side of the rotating gear 503.

The output end of the micro motor 502 has a bidirectional rotation function, and when the micro motor 502 is powered on, the output end drives the rotating gear 503 to rotate.

In this embodiment, as shown in fig. 6, the lifting rod 504 is movably sleeved in the stabilizing groove 501, and the side portion of the lifting rod 504 is provided with gear patterns and meshed with the gear patterns on the side portion of the rotating gear 503.

Under the action force of the mutual meshing of the gear patterns between the rotating gear 503 and the rear side surface of the lifting rod 504, when the rotating gear 503 rotates clockwise, the lifting rod 504 gradually moves downwards, and when the rotating gear 503 rotates anticlockwise, the lifting rod 504 gradually moves upwards, so that the depth of the lifting rod 504 entering the water bottom is adjusted, and the effects that the probe rope 407 and the probe arranged at the front end directly enter the water bottom to float and the water quality of the water bottom cannot be collected vertically downwards are avoided.

In this embodiment, as shown in fig. 6, the lifting rod 504 is provided with a stabilizing chute 505 at both sides of the interior thereof and between the middle portion and the tail end thereof, a spring rod 506 is fixedly connected to the front end of the interior of the stabilizing chute 505, a sliding block 507 is movably connected to the interior of the stabilizing chute 505, the front end of the spring rod 506 is fixedly connected to the tail end of the sliding block 507, and an auxiliary roller 508 is movably hinged to the opposite inner side surface of the sliding block 507.

The spring rod 506 has an unfolding acting force, so that the sliding block 507 is pushed forward, the sliding block 507 drives the hinged auxiliary roller 508 to approach the limiting roller 509, clamping and conveying of the probe rope 407 are realized, and the function of winding and unwinding the probe rope 407 is realized.

In this embodiment, as shown in fig. 8, the middle parts of two sides of the inside of the lifting rod 504 are movably hinged with a limiting roller 509, two ends of the limiting roller 509 are fixedly connected with a driving gear plate 510, a gear motor 513 is fixedly connected between the inside of the lifting rod 504 and the middle part and the tail end far away from the lifting rod, the output end of the gear motor 513 is fixedly connected with a driving gear plate 512, and simultaneously the driving gear plate 512 and the side parts of the driving gear plate 510 are movably sleeved with a gear plate crawler 511.

Wherein, the output end of gear motor 513 possesses the function of two-way rotation, after gear motor 513 operates, makes the output end drive the rotation of drive tooth piece 512, makes tooth piece track 511 carry out the transmission this moment to drive the effect that drive tooth piece 510 followed the synchronous rotation of drive tooth piece 512 to the same direction, make spacing cylinder 509 rotate this moment, rotate when spacing cylinder 509 clockwise, realize the outward output to probe rope 407, and spacing cylinder 509 anticlockwise rotation realizes inwards returning to probe rope 407.

When the sewage monitoring device for rural environment management works, the air is conveyed into the air charging ring 102 to fully expand the air charging ring 102, then the floating plate 101 is placed on the water surface to float, at the moment, the driving motor 208 is controlled to operate, the output end drives the driving gear 207 to rotate clockwise, the transmission caterpillar 206 at the side part of the driving gear 207 drives the transmission gear 205 to rotate, the winding rod 203 is conveyed downwards aiming at the hauling rope 204 sleeved at the side part in a clockwise manner until the hauling cone at the bottom end of the hauling rope 204 sinks into the water, the position of the floating plate 101 is fixed, at the moment, the driving motor 301 is controlled to operate, the output end drives the transmission disc 302 to rotate clockwise or anticlockwise, the rotation disc 303 is gradually rotated under the action force of mutual engagement between the gear patterns at the side part of the transmission disc 302 and the gear patterns at the side part of the rotation disc 303, and after the monitoring collection position corresponding to the bottom end of the lifting rod 504 is adjusted, the driving motor 301 is controlled to stop operating, at this time, the micro motor 502 is controlled to operate, the output end of the micro motor 502 drives the rotating gear 503 to rotate clockwise, the lifting rod 504 is gradually moved downwards under the action force of mutual engagement between the gear pattern on the side part of the rotating gear 503 and the gear pattern arranged on the corresponding surface of the lifting rod 504 until the lifting rod 504 reaches the depth required to be collected, the limit roller 406 is made to approach the rotating roller 410 under the action force of the tension spring 404 pushing the moving block 405 to move forwards, the clamping of the probe rope 407 is realized, the spring rod 506 pushes the sliding block 507, the auxiliary roller 508 is made to approach the limit roller 509, the conduction motor 409 and the gear motor 513 are controlled to operate simultaneously under the state of approaching the probe rope 407, the probe rope 407 is gradually conveyed to the bottom end inside the lifting rod 501, the water with the required depth is collected, and feed back to water quality detector 109, detect the pollution condition of quality of water through water quality detector 109, throw light on the surface of water through light 106 at night simultaneously to turn to the regulation through steering mechanism 107, make the monitoring probe 108 on top monitor the surface of water, and in daytime, shine on solar panel 111 through sunshine, solar panel 111 converts the light source of receiving into electric energy, stores in the power box of device, supplies the whole power consumption of device to use.

The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (10)

1. The utility model provides a rural sewage monitoring device for environmental management, includes cursory subassembly (1), its characterized in that: the utility model provides a cursory subassembly (1) is including cursory board (101), has fixed subassembly (2) at the internally mounted of cursory board (101) tail end, and mid-mounting of cursory board (101) has regulation and control subassembly (3) simultaneously, regulation and control subassembly (3) are including cursory board (101) top central point put articulated rolling disc (303), are received rope subassembly (4) in the one end fixedly connected with at rolling disc (303) top, and rise accuse subassembly (5) are installed at the other end at regulation and control subassembly (3) top.

2. The sewage monitoring device for rural environment management according to claim 1, wherein the side part of the floating plate (101) is fixedly connected with an inflatable ring (102), the side part of the inflatable ring (102) is provided with a gas transmission interface, and a sealing cover (103) is connected at the gas transmission interface in a threaded manner.

3. The sewage monitoring device for rural environment management according to claim 2, wherein the four direction angles at the top of the float plate (101) are all fixedly connected with a supporting rod (104), the top of the supporting rod (104) is fixedly connected with an equipment mounting plate (105), the top of the front end of the equipment mounting plate (105) is fixedly connected with an illuminating lamp (106), meanwhile, the top of the equipment mounting plate (105) is far away from a central position and a front end, a steering mechanism (107) is installed, the top of the steering mechanism (107) is fixedly connected with a monitoring probe (108), the top of the equipment mounting plate (105) is far away from a tail end and a central position, a water quality detector (109) is fixedly connected with the tail end of the top of the equipment mounting plate (105), a hinge groove (110) is formed in the tail end of the top of the equipment mounting plate (105), and a solar panel (111) is movably hinged in the hinge groove (110).

4. The sewage monitoring device for rural environment management according to claim 1, wherein the fixing component (2) comprises a rope winding box (201) fixedly connected with the tail end of the floating plate (101), two ends inside the rope winding box (201) are movably hinged with limit side plates (202), opposite inner side surfaces of the limit side plates (202) are fixedly connected with winding rods (203), pulling ropes (204) are movably sleeved on the side parts of the winding rods (203), meanwhile, transmission gears (205) are fixedly connected with the outer side surfaces of the limit side plates (202) at the right end, transmission tracks (206) are movably sleeved on the side parts of the transmission gears (205), driving gears (207) are movably sleeved on the inner side surfaces of the front ends of the transmission tracks (206), meanwhile, driving motors (208) are mounted in the inner side parts of the tail end of the floating plate (101), and output ends of the driving motors (208) are fixedly connected with the center positions of the side parts of the driving gears (207).

5. The rural environment management sewage monitoring device according to claim 4, wherein the top of the floating plate (101) is fixedly connected with a transmission motor (301) at the side part far away from the rotating disc (303), the output end of the transmission motor (301) is fixedly connected with a transmission disc (302), and meanwhile, the transmission disc (302) and the side part of the rotating disc (303) are both provided with gear patterns, and the gear patterns are meshed with each other.

6. The sewage monitoring device for rural environment management according to claim 1, wherein the rope collecting component (4) comprises a rope collecting box (401) fixedly connected with one end of the top of the rotating disc (303), two ends inside the rope collecting box (401) are fixedly connected with a track plate (402), a track groove (403) is formed in the inner side face opposite to the track plate (402), a tension spring (404) is fixedly connected with the tail end inside the track groove (403), a movable block (405) is fixedly connected with the front end of the tension spring (404), a limit roller (406) is movably hinged to the inner side face opposite to the movable block (405), a probe rope (407) is movably sleeved on the side portion of the limit roller (406), a sewage detection probe is mounted at the front end of the probe rope (407), hinge buttons (408) are respectively arranged at the front ends of the inner side faces opposite to the track plate (402), a rotary roller (410) is movably hinged to the inner side faces opposite to the hinge buttons (408), a conducting motor (409) is fixedly connected to the outer side face of the front end of the left track plate (402), and the conducting motor (409) is fixedly connected to one end of the rotary roller (410).

7. The sewage monitoring device for rural environment management according to claim 1, wherein the lifting control assembly (5) comprises a stabilizing groove (501) formed in the other end of the top of the rotating disc (303), a micro motor (502) is fixedly connected to the side part of the stabilizing groove (501), meanwhile, a rotating gear (503) is movably hinged to the tail end inside the stabilizing groove (501), and the output end of the micro motor (502) is fixedly connected to the central position of the side part of the rotating gear (503).

8. The rural environment management sewage monitoring device according to claim 7, wherein the lifting rod (504) is movably sleeved in the stabilizing groove (501), and the side part of the lifting rod (504) is provided with gear patterns which are meshed with the gear patterns on the side part of the rotating gear (503).

9. The sewage monitoring device for rural environment management according to claim 1, wherein the lifting rod (504) is provided with a stable sliding groove (505) on two sides of the inside of the lifting rod, far away from between the middle part and the tail end, a spring rod (506) is fixedly connected to the front end of the inside of the stable sliding groove (505), a sliding block (507) is movably connected to the inside of the stable sliding groove (505), the front end of the spring rod (506) is fixedly connected to the tail end of the sliding block (507), and an auxiliary roller (508) is movably hinged to the opposite inner side surface of the sliding block (507).

10. The sewage monitoring device for rural environment management according to claim 9, wherein the middle parts of two sides of the inside of the lifting rod (504) are movably hinged with a limiting roller (509), two ends of the limiting roller (509) are fixedly connected with a transmission toothed disc (510), a gear motor (513) is fixedly connected between the inside of the lifting rod (504) and the tail end far away from the middle part, the output end of the gear motor (513) is fixedly connected with a driving toothed disc (512), and simultaneously the driving toothed disc (512) and the side parts of the transmission toothed disc (510) are movably sleeved with a toothed disc crawler (511).