CN219493605U - Municipal administration pipeline water environment detector - Google Patents

Abstract

The application relates to a municipal pipeline water environment detector relates to the technical field of water environment monitoring, including removing frame and detector body, remove and be provided with sampling mechanism on the frame, sampling mechanism includes sampling dolly, sampling pipe and seal assembly. The lifting assembly and the moving assembly are matched to drive the sampling trolley to move, the sealing assembly is opened, so that the opening end of one sampling tube is communicated with the pipeline body, water flows into the sampling tube, the sealing assembly is closed, then the sampling trolley continues to move until the sampling trolley moves to the next sampling point, the opening end of the sampling tube which is not sampled is opened, water sample sampling of a plurality of sampling points is completed through the circulation, after sampling is completed, the moving assembly and the lifting assembly are matched to drive the sampling trolley to move back, the connecting mechanism is opened, the sampling tube is taken down, water samples are detected on site through the detector body, and therefore single sampling of the water samples of the sampling points is achieved, and the water environment detection efficiency of municipal pipelines is improved.

Description

Municipal administration pipeline water environment detector

Technical Field

The application relates to the technical field of water environment monitoring, in particular to a municipal pipeline water environment detector.

Background

The water environment monitoring is to use physical, chemical and biological technical means to perform qualitative, quantitative and systematic comprehensive analysis on pollutants and related components thereof to explore the change rule of research. The water environment monitoring provides reliable basic data for water and scientific basis for the effect evaluation of treatment measures.

The object of water environment monitoring can be divided into nano sewage body water quality monitoring and: the former includes surface water (river, lake, reservoir, sea water) and groundwater; the latter includes domestic sewage, hospital sewage and various industrial waste waters, and sometimes agricultural water withdrawal, primary rainwater and acid mine drainage, etc.; the municipal pipeline requiring water environment monitoring comprises a water supply pipeline, a drainage pipeline and a sewage pipeline, and the flow of water environment monitoring mainly comprises the steps of determining a detection project, sampling the water environment, detecting the water environment sample on site, reserving the water environment sample, detecting the water environment in a laboratory, processing data and reporting.

The water supply pipeline can be used for sampling and detecting at a tap water company or a using terminal, the water quality detection of the drainage pipeline and the sewage pipeline is usually carried to an inspection well by a sampling bottle and a water quality detector, the inspection well is opened, a counterweight stone is bound on the sampling bottle, the sampling bottle is hung into a municipal pipeline through the inspection well, water flows into the sampling bottle, then the sampling bottle is hung out, the water quality detector is used for detecting and recording basic data on site, the rest samples are reserved for laboratory microorganism detection and sample reserving, and then all equipment is transported to the next sampling point for sampling and detecting.

However, the sampling bottle can only sample the water sample of one sampling point at a time, and the whole equipment needs to be carried for multiple times to sample the next sampling point in sequence, so that the time for sampling the water environment is increased, the time for detecting the water environment of the municipal pipeline is prolonged, and the efficiency of detecting the water environment of the municipal pipeline is reduced.

Disclosure of Invention

In order to improve municipal pipeline water environment detection's efficiency, this application provides a municipal pipeline water environment detector.

The application provides a municipal administration pipeline water environment detector adopts following technical scheme:

the utility model provides a municipal pipeline water environment detector, includes and removes the frame and set up the detector body on removing the frame, remove and be provided with the sampling mechanism that is used for taking a sample to the water sample of pipeline body on the frame, sampling mechanism includes:

the sampling trolley is arranged on the moving frame in a sliding manner and is arranged on the pipeline body in a sliding manner through the moving assembly, and the lifting assembly for driving the sampling trolley to move is arranged on the moving frame;

the sampling pipes are provided with a plurality of sampling pipes, the sampling pipes are detachably arranged on the sampling trolley through a connecting mechanism, and one ends of the sampling pipes are in an opening state and are used for sampling water samples at different positions;

and the sealing component is arranged on the sampling trolley, is connected with the sampling pipe and is used for controlling the opening and closing of the single sampling pipe.

Through adopting above-mentioned technical scheme, carry the sample point with the movable frame, the hoist and mount subassembly starts to place the sample dolly in the pipeline body, the movable assembly starts to drive the sample dolly and removes, when needs sample, the closed assembly is opened and is made the open end and the pipeline body intercommunication of one of them sample pipe, in the rivers flow direction sample pipe, the closed assembly is closed, then the sample dolly continues to remove, until remove to next sample point, the open end of the sampling pipe of non-sample is opened, accomplish the water sample sampling of a plurality of sample points with this circulation, after the sampling finishes, the movable assembly drives the sample dolly and moves back, the hoist and mount subassembly drives the sample dolly and moves back to movable frame department, open coupling mechanism, take off the sample pipe, detect the scene through the detector body, thereby reduce the number of times of carrying integral equipment, thereby the time of sampling has been practiced thrift, municipal pipeline water environment detection's time has been shortened, therefore municipal pipeline's water environment detection's efficiency has been improved.

Optionally, the closure assembly includes:

the sealing cover is clamped and arranged on the sampling tube and used for shielding the opening end;

the electric push rod is arranged on the sampling trolley, a connecting rod is arranged on the electric push rod, and the sealing cover is in threaded connection with the connecting rod.

By adopting the technical scheme, in the initial state, the sealing cover is clamped and installed on the sampling pipe, when sampling is needed, the electric push rod is started to drive the sealing cover to separate from the sampling pipe, after a water sample enters the sampling pipe, the electric push rod is started to drive the sealing cover to be clamped and installed on the sampling pipe so as to seal the opening end of the sampling pipe, after all the sampling pipes are sampled, the lifting assembly drives the sampling trolley to return to the ground, then the connecting mechanism is opened, a detector holds the joint of the sealing cover and the sampling pipe, the whole rotation sampling pipe drives the sealing cover to separate from the connecting rod, then the sealing cover is stirred to separate from the opening end of the sampling pipe, and the sensor detection element of the detector body extends into the sampling pipe to carry out field detection, so that the collection and detection of the water samples at a plurality of places are realized, and the water environment sampling time is saved; after the sampling point is reached, the sealing cover is opened again, so that the probability that water flow of a non-sampling point enters the sampling pipe is reduced, the accuracy and stability of water environment sampling are improved, and the efficiency of water environment detection of municipal pipelines is improved.

Optionally, the moving assembly includes:

the moving wheel rotates and is arranged on the sampling trolley and is abutted against the pipeline body;

and the moving motor is arranged on the sampling trolley, and an output shaft is connected with the moving wheel.

Through adopting above-mentioned technical scheme, the mobile motor starts to drive and removes the wheel and rotate, the mobile wheel rotates and drives the sample dolly and remove on the pipeline body, remove to the sampling point after, the mobile motor pauses, the sampling pipe takes a sample, after the sample finishes, the mobile motor starts again and drives the sample dolly and remove to next sampling point, until after all sampling pipes all sample finishes, the mobile motor reversal drives and removes the wheel and reversely rotate, hoist and mount subassembly starts simultaneously and carries out the pullback to the sample dolly, thereby realize the removal of mobile dolly, thereby the convenience of carrying out water sample collection in municipal pipeline has been improved, municipal pipeline's water environment detection's time has been shortened, therefore municipal pipeline's water environment detection's efficiency has been improved.

Optionally, the hoisting assembly includes:

the winch is arranged on the movable frame and is wound with a connecting rope;

the connecting hook is arranged on the connecting rope and hooked on the sampling trolley.

Through adopting above-mentioned technical scheme, the hoist engine starts and makes the connecting rope lengthen, until the movable pulley of connecting the dolly is contradicted on this internal diapire of pipeline, then the movable motor starts and drives the movable dolly and remove, the connecting rope lasts the extension, after the sampling, the hoist engine starts and carries out the rolling to the connecting rope, so drive the sampling dolly and move back, until the sampling dolly breaks away from the pipeline body and get back to ground, so as to realize the removal of sampling dolly, thereby the convenience of carrying out water sample collection in municipal pipeline has been improved, municipal pipeline water environment detection's time has been shortened, therefore municipal pipeline's water environment detection's efficiency has been improved.

Optionally, the connection mechanism includes:

the connecting bottom belt is rotatably arranged on the sampling trolley and is abutted against the sampling pipe;

the connecting buckle belt is rotatably arranged on the sampling trolley and is abutted against the sampling pipe;

the connecting assembly is arranged on the connecting bottom strap and is connected with the connecting buckle strap.

Through adopting above-mentioned technical scheme, after the sample finishes, open coupling assembling, stir the connecting end area and keep away from each other with the connector link area, handheld sampling pipe and closing cap rotate and make the closing cap break away from the connecting rod, then can make the sampling pipe keep away from the sample dolly, during the installation, conflict the sampling pipe on the connecting end area, then rotate the connector link area and conflict on the sampling pipe, lock coupling assembling and carry out spacingly to the sampling pipe, thereby realize the detachable connection of sampling pipe and sample dolly, thereby the convenience of carrying out water sample collection in municipal pipeline has been improved, municipal pipeline water environment detection's time has been shortened, therefore municipal pipeline's water environment detection's efficiency has been improved.

Optionally, the connection assembly includes:

the connecting ring is arranged on the connecting bottom strap, the connecting buckle strap is arranged on the connecting ring in a penetrating way, and a plurality of positioning holes are formed in the connecting buckle strap at intervals;

the positioning rod is rotatably arranged on the connecting ring and penetrates through the positioning hole;

the positioning ring is arranged on the connecting bottom belt in a sliding manner and sleeved on the connecting buckle belt.

Through adopting above-mentioned technical scheme, pulling connector strip breaks away from the holding ring, then stir the locating lever and break away from the locating hole, pulling connector strip breaks away from the holding ring at last, then can take off the sampling pipe and detect the water sample, during the installation, conflict the sampling pipe on the connecting bottom band, rotate the connector strip and conflict on the sampling pipe, pass the connector strip, wear the locating lever to establish on suitable locating hole simultaneously for the connector strip supports tightly on the sampling pipe, wear to establish the connector strip on the holding ring at last, the holding ring is spacing to connecting bottom band and connector strip, with this dismantlement change and the installation location that realizes the sampling pipe, thereby the convenience of change and installation location is dismantled to the sampling pipe has been improved.

Optionally, a displacement sensor is arranged on the sampling trolley, and the displacement sensor is electrically connected with the mobile motor and the electric push rod.

Through adopting above-mentioned technical scheme, displacement sensor detects the displacement of sampling dolly in real time, when reaching every sampling point, and the mobile motor is suspended, and the electric putter starts simultaneously to this accuracy that carries out the water sampling in municipal pipeline is realized, thereby has improved municipal pipeline's water environment detection's efficiency.

Optionally, be provided with the universal wheel that is convenient for remove and have the auto-lock on the removal frame.

Through adopting above-mentioned technical scheme, the universal wheel has improved the convenience that removes the frame to practice thrift the time of carrying the frame that removes, with this efficiency that has improved municipal pipeline's water environment and detected.

In summary, the present application includes at least one of the following beneficial technical effects:

the lifting assembly starts to place the sampling trolley into the pipeline body, the moving assembly starts to drive the sampling trolley to move, when sampling is needed, the sealing assembly is opened, the opening end of one sampling pipe is communicated with the pipeline body, water flows into the sampling pipe, the sealing assembly is closed, then the sampling trolley continues to move until the sampling trolley moves to the next sampling point, the opening end of the sampling pipe which is not sampled is opened, water sample sampling of a plurality of sampling points is completed in a circulating mode, after sampling is completed, the moving assembly and the lifting assembly cooperate to drive the sampling trolley to move back to the moving frame, the connecting mechanism is opened, the sampling pipe is taken down, water samples are detected on site through the detector body, so that the water samples of a plurality of sampling points are sampled once, the times of carrying integral equipment are reduced, the time of water environment sampling is saved, the time of municipal pipeline water environment detection is shortened, and the efficiency of municipal pipeline water environment detection is improved.

Drawings

FIG. 1 is a schematic overall structure of the present application;

FIG. 2 is a schematic illustration of the sampling mechanism of the present application, with the manhole and the pipe body partially sectioned;

FIG. 3 is a schematic view of the structure of the moving assembly and the connecting mechanism of the present application;

FIG. 4 is a schematic structural view of the connection assembly of the present application with one of the connecting straps hidden;

fig. 5 is an exploded view of the closure assembly of the present application.

Reference numerals: 1. a moving rack; 11. a detector body; 111. a pipe body; 12. a universal wheel; 13. an armrest; 14. a control box; 15. an inspection well; 16. a displacement sensor; 2. a sampling mechanism; 21. a sampling trolley; 211. a fixing ring; 212. a contact plate; 22. a sampling tube; 23. a closure assembly; 231. a closing cap; 232. an electric push rod; 233. a seal ring; 234. a connecting rod; 3. a moving assembly; 31. a moving wheel; 32. a moving motor; 4. hoisting the assembly; 41. a hoist; 411. a connecting cable; 42. a connecting hook; 5. a connecting mechanism; 51. connecting a bottom belt; 52. connecting the buckle belt; 521. positioning holes; 53. a connection assembly; 531. a connecting ring; 532. a positioning rod; 533. and a positioning ring.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-5.

The displacement sensor 16 in the present embodiment is of the type MPSFS-M.

The embodiment of the application discloses municipal administration pipeline water environment detector.

Referring to fig. 1 and 2, a municipal pipeline water environment detector, including removing frame 1 and fixed mounting detector body 11 on removing frame 1 upper surface, be provided with on removing frame 1 and be used for carrying out sampling mechanism 2 of taking a sample to the water sample in the pipeline body 111, remove four corners of frame 1 lower surface and all rotate and install universal wheel 12, universal wheel 12 has the auto-lock function and be convenient for remove, remove and be convenient for push's handrail 13 on the 1 lateral wall of frame, remove simultaneously on the 1 upper surface of frame fixed mounting have control box 14.

Referring to fig. 1 and 2, the sampling mechanism 2 includes a sampling trolley 21, the sampling trolley 21 is vertically slidably disposed on a moving frame 1 and horizontally slidably disposed on a pipe body 111 through a moving assembly 3, and a hoisting assembly 4 for driving the sampling trolley 21 to move is disposed on the moving frame 1; in the embodiment of the present application, the inspection well 15 is taken as an example of a sampling port, and any position with an opening of the pipe body 111 may be selected in practical application.

Referring to fig. 1 and 2, the moving frame 1 is located above the manhole 15, the manhole 15 is communicated with the pipe body 111, the hoisting assembly 4 comprises a hoist 41 and a connecting hook 42, the hoist 41 is fixedly installed on the upper surface of the moving frame 1 and located above the manhole 15, and a connecting rope 411 is wound on the hoist 41; the connecting hook 42 is fixedly arranged at one end of the connecting rope 411, which is far away from the winch 41, the tail part of the sampling trolley 21 is fixedly provided with a fixing ring 211, and the connecting hook 42 is hooked on the fixing ring 211.

Referring to fig. 2 and 3, the moving assembly 3 includes moving wheels 31 and a moving motor 32, the moving wheels 31 are provided in four, four moving wheels 31 are provided on the lower surface of the sampling trolley 21 at intervals, the moving wheels 31 are horizontally rotatably installed on the lower surface of the sampling trolley 21, and the lower surface of the moving wheels 31 is abutted against the inner bottom wall of the pipe body 111; the two moving motors 32 are provided, and the two moving motors 32 are in one-to-one correspondence with the two moving wheels 31 away from the fixed ring 211.

Referring to fig. 2 and 3, a moving motor 32 is fixedly installed on the lower surface of the sampling trolley 21, an output shaft of the moving motor 32 is in a horizontal state and coincides with an axis of the moving wheel 31, the output shaft of the moving motor 32 is connected with the moving wheel 31 and is used for driving the moving wheel 31 to rotate, and the moving motor 32 has waterproofness and is electrically connected with the control box 14; the displacement sensor 16 is fixedly mounted on the upper surface of the end, far away from the connecting hook 42, of the sampling trolley 21, and the displacement sensor 16 is electrically connected with the control box 14 and used for detecting the displacement of the sampling trolley 21 in real time.

Referring to fig. 2 and 3, the moving frame 1 is pushed to the upper side of the inspection well 15, the inspection well 15 is opened, the connecting hook 42 is hooked on the fixing ring 211, the sampling trolley 21 is vertically placed in the inspection well 15, the winch 41 is started to enable the connecting cable 411 to be gradually prolonged, the sampling trolley 21 is gradually lowered until the moving wheel 31 is abutted against the inner bottom wall of the pipeline body 111, the moving motor 32 and the displacement sensor 16 are started, the moving motor 32 drives the sampling trolley 21 to move in the pipeline body 111, and meanwhile, the displacement sensor 16 detects the position of the sampling trolley 21 in real time.

Referring to fig. 2 and 3, the sampling mechanism 2 further includes a plurality of sampling tubes 22, and the sampling tubes 22 are provided with a plurality of sampling tubes 22, in this embodiment, taking four sampling tubes 22 as an example, the four sampling tubes 22 are detachably disposed on the outer wall of the sampling trolley 21 through the connection mechanism 5, and one end of the sampling tube 22, which is far away from the fixing ring 211, is in an opening state and is used for sampling water samples at different positions.

Referring to fig. 2 and 3, the connection mechanisms 5 are provided with four sets and are in one-to-one correspondence with the sampling tubes 22, each set of connection mechanisms 5 includes two, and in the following, description will be given by taking only one connection mechanism 5 located on the outer side wall of the sampling cart 21 as an example, the connection mechanism 5 includes a connection base band 51, a connection buckle band 52, and a connection assembly 53.

Referring to fig. 3 and 4, the connection bottom belt 51 is vertically rotatably installed on the outer sidewall of the sampling trolley 21, and the connection bottom belt 51 has waterproofness, the inner wall of the connection bottom belt 51 is abutted against the outer wall of the sampling tube 22, an abutting plate 212 is fixedly installed on the outer sidewall of the sampling trolley 21, and one end of the sampling tube 22, which is close to the fixing ring 211, abuts against the outer sidewall of the abutting plate 212; the connecting buckle belt 52 is vertically and rotatably arranged on the outer side wall of the sampling trolley 21 and is positioned above the connecting bottom belt 51, the connecting buckle belt 52 is close to the inner wall of the connecting bottom belt 51 and is abutted against the outer wall of the sampling tube 22, and the connecting buckle belt 52 has waterproofness.

Referring to fig. 3 and 4, the connection assembly 53 is disposed on the connection base belt 51 and connected with the connection buckle belt 52, the connection assembly 53 includes a connection ring 531, a positioning rod 532 and a positioning ring 533, the connection ring 531 is fixedly mounted at one end of the connection base belt 51 far away from the sampling trolley 21, the connection buckle belt 52 horizontally passes through the connection ring 531, and a plurality of positioning holes 521 are spaced apart from the connection buckle belt 52; the positioning rod 532 is horizontally rotatably installed on one end of the connecting ring 531, which is close to the connecting bottom belt 51, and the positioning rod 532 is arranged on the positioning hole 521 in a penetrating manner and is abutted against the upper surface of one end of the connecting ring 531, which is far away from the connecting bottom belt 51; the positioning ring 533 is slidably mounted on the connection base belt 51 along the length direction of the connection base belt 51, and the positioning ring 533 is sleeved on the connection buckle belt 52 for limiting.

Referring to fig. 2 and 3, the sampling mechanism 2 further includes a closing member 23, wherein the closing member 23 is disposed on the sampling trolley 21 and connected to the sampling tube 22 for controlling the opening and closing of the individual sampling tubes 22, and the closing member 23 is provided in plurality and in one-to-one correspondence with the sampling tubes 22, and the following description will be given by taking only one closing member 23 located on the outer side wall of the sampling trolley 21 as an example.

Referring to fig. 3 and 5, the closing assembly 23 includes a closing cap 231 and an electric push rod 232, the closing cap 231 is horizontally slidably disposed on the sampling trolley 21 and is mounted on the opening end of the sampling tube 22 in a clamping manner, the closing cap 231 is used for shielding the opening end of the sampling tube 22, a sealing ring 233 for sealing is fixedly mounted on the outer side wall of the closing cap 231, which is close to the opening end of the sampling tube 22, and the sealing ring 233 abuts against the inner wall of the opening end of the sampling tube 22.

Referring to fig. 3 and 5, the electric push rod 232 is fixedly installed on the outer sidewall of the sampling trolley 21 and electrically connected with the control box 14, meanwhile, the electric push rod 232 has waterproof performance, the piston end of the electric push rod 232 coincides with the axis of the closing cap 231, the connecting rod 234 is coaxially and fixedly installed on the piston end of the electric push rod 232, and one end of the closing cap 231 far away from the sampling tube 22 is in threaded connection with the connecting rod 234.

Referring to fig. 3 and 5, when the sampling trolley 21 moves to the first sampling point, the moving motor 32 is suspended, the electric push rod 232 is started to drive the closing cap 231 to be separated from the sampling tube 22, the water sample flows into the sampling tube 22, after the sampling time is reached, the electric push rod 232 is started to enable the closing cap 231 to move back until the clamping connection is installed on the sampling tube 22, then the moving motor 32 is restored, and when the sampling trolley 21 moves to the next sampling point, the second electric push rod 232 is started to drive the closing cap 231 on the second sampling tube 22 to be separated from the sampling tube 22, so that the sampling is repeated until all the sampling tubes 22 are completely sampled.

Referring to fig. 2 and 5, the hoist 41 winds the connecting cable 411, and simultaneously, the mobile motor 32 drives the mobile wheel 31 to reversely rotate, the sampling trolley 21 moves back to the mobile frame 1, the connecting buckle belt 52 is shifted to be separated from the positioning ring 533, the positioning rod 532 is rotated to be separated from the positioning hole 521, the labor connecting buckle belt 52 is separated from the connecting ring 531, then the inspector holds the joint of the sampling pipe 22 and the sealing cover 231, the electric push rod 232 starts to drive the sampling pipe 22 and the sealing cover 231 to integrally move, so that the sampling pipe 22 is separated from the interference plate 212, then the inspector integrally rotates the sampling pipe 22 and the sealing cover 231 until the sealing cover 231 is separated from the connecting rod 234, then the sealing cover 231 is shifted to be separated from the sampling pipe 22, and the sensor detecting element of the inspector body 11 extends into the sampling pipe 22 for detection, so that the times of carrying the whole equipment are reduced, the time of water environment sampling is saved, the time of municipal pipeline detection is shortened, and the water environment detection efficiency of the municipal pipeline is improved.

The working principle of the embodiment of the application is as follows:

the sampling trolley 21 is vertically placed in the inspection well 15, the winch 41 is started to enable the sampling trolley 21 to gradually descend until the moving wheel 31 is abutted against the bottom wall in the pipeline body 111, the moving motor 32 is started to drive the sampling trolley 21 to move in the pipeline body 111, meanwhile, the displacement sensor 16 detects the position of the sampling trolley 21 in real time, when the sampling trolley 21 moves to a first sampling point, the moving motor 32 is suspended, the electric push rod 232 is started to drive the sealing cover 231 to separate from the sampling pipe 22, a water sample flows into the sampling pipe 22, after the sampling time is reached, the electric push rod 232 is started to enable the sealing cover 231 to move back until the clamping connection is installed on the sampling pipe 22, then the moving motor 32 is restored, the sampling trolley 21 moves to the next sampling point, the repeated operation is realized, the sampling of all the sampling pipes 22 is realized, the sampling and the detection of the water samples of a plurality of sampling points are carried out once, so that the frequency of carrying the whole equipment is reduced, the time for sampling the water environment in the municipal pipeline is saved, the time for detecting the water environment of the municipal pipeline is shortened, and the water environment detection efficiency of the municipal pipeline is improved.

After the sampling is finished, the mobile motor 32 and the winch 41 are matched to enable the sampling trolley 21 to move back to the mobile frame 1, the connecting buckle belt 52 is stirred to be far away from the connecting bottom belt 51, the electric push rod 232 is started to drive the sampling pipe 22 to be far away from the interference plate 212, then the sampling pipe 22 and the sealing cover 231 are used for integrally rotating, the sealing cover 231 is separated from the electric push rod 232, then water samples can be detected, and therefore the convenience of detecting the water samples of a plurality of sampling points is improved, and the efficiency of water environment detection of municipal pipelines is improved.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. The utility model provides a municipal administration pipeline water environment detector, includes and removes frame (1) and detector body (11) of setting on removing frame (1), its characterized in that: be provided with on the removal frame (1) and be used for taking a sample in the water sample of pipeline body (111) sampling mechanism (2), sampling mechanism (2) include:

the sampling trolley (21) is arranged on the movable frame (1) in a sliding manner and arranged on the pipeline body (111) in a sliding manner through the movable assembly (3), and the movable frame (1) is provided with a hoisting assembly (4) for driving the sampling trolley (21) to move;

the sampling pipes (22) are arranged, the sampling pipes (22) are detachably arranged on the sampling trolley (21) through the connecting mechanism (5), and one ends of the sampling pipes (22) are in an opening state and are used for sampling water samples at different positions;

and the sealing assembly (23) is arranged on the sampling trolley (21), is connected with the sampling pipe (22) and is used for controlling the opening and closing of the single sampling pipe (22).

2. The municipal pipeline water environment detector according to claim 1, wherein: the closure assembly (23) comprises:

the sealing cover (231) is clamped and arranged on the sampling tube (22) and used for shielding the opening end;

the electric push rod (232), electric push rod (232) set up on sampling dolly (21), be provided with connecting rod (234) on electric push rod (232), closing cap (231) threaded connection is on connecting rod (234).

3. The municipal pipeline water environment detector according to claim 2, wherein: the moving assembly (3) comprises:

the movable wheel (31) is rotatably arranged on the sampling trolley (21) and is abutted against the pipeline body (111);

and the moving motor (32) is arranged on the sampling trolley (21), and the output shaft is connected with the moving wheel (31).

4. A municipal pipe water environment detector according to claim 3, wherein: the hoisting assembly (4) comprises:

a winch (41), wherein the winch (41) is arranged on the movable frame (1), and a connecting rope (411) is wound on the winch (41);

and a connecting hook (42), wherein the connecting hook (42) is arranged on the connecting rope (411) and is hooked on the sampling trolley (21).

5. The municipal pipeline water environment detector according to claim 2, wherein: the connection mechanism (5) comprises:

the connecting bottom belt (51) is rotatably arranged on the sampling trolley (21) and is abutted against the sampling tube (22);

the connecting buckle belt (52) is rotatably arranged on the sampling trolley (21) and is abutted against the sampling tube (22);

and the connecting component (53) is arranged on the connecting bottom belt (51) and is connected with the connecting buckle belt (52).

6. The municipal pipeline water environment detector according to claim 5, wherein: the connection assembly (53) comprises:

the connecting ring (531), the connecting ring (531) is arranged on the connecting bottom belt (51), the connecting buckle belt (52) is arranged on the connecting ring (531) in a penetrating way, and a plurality of positioning holes (521) are formed in the connecting buckle belt (52) at intervals;

the positioning rod (532) is rotatably arranged on the connecting ring (531) and penetrates through the positioning hole (521);

and the positioning ring (533) is slidably arranged on the connecting bottom belt (51) and sleeved on the connecting buckle belt (52).

7. The municipal pipeline water environment detector according to claim 1, wherein: the sampling trolley (21) is provided with a displacement sensor (16), and the displacement sensor (16) is electrically connected with a mobile motor (32) and an electric push rod (232).

8. The municipal pipeline water environment detector according to claim 1, wherein: the movable frame (1) is provided with a universal wheel (12) which is convenient to move and is provided with self-locking.