CN220542504U - Remote monitoring device for drainage engineering sampling - Google Patents

Abstract

The utility model relates to the technical field of drainage engineering, in particular to a remote monitoring device for sampling in drainage engineering, which comprises a fixed cylinder, wherein a control center is fixedly arranged in the fixed cylinder, a driving roller is rotatably arranged in the fixed cylinder through a bearing, a movable frame for driving the driving roller to rotate positively and negatively is slidably arranged in the fixed cylinder, a cylinder fixedly connected with the movable frame is fixedly arranged in the fixed cylinder, a first winding wheel is fixedly sleeved on the driving roller, a first traction rope is wound on the first winding wheel, a sampling box is fixedly connected on the first traction rope, a water body can drive a buoyancy plate to vertically move upwards, the buoyancy plate drives a second winding wheel to rotate through meshing connection of a driving rack and a driven gear, and the second winding wheel drives a sealing piece to enter a water inlet pipe through the second traction rope to seal the water inlet pipe, so that leakage caused by upward movement of the sampling box when the water inlet pipe still keeps an opening state after the sampling box is collected is avoided.

Description

Remote monitoring device for drainage engineering sampling

Technical Field

The utility model relates to the technical field of drainage engineering, in particular to a remote monitoring device for drainage engineering sampling.

Background

The drainage engineering is the engineering for collecting and discharging various kinds of waste water, superfluous surface water and underground water in the process of human domestic sewage and production, and the main facilities are various levels of drainage channels or pipelines and auxiliary buildings thereof, and water pumps or other water lifting machines, sewage treatment buildings and the like can be additionally arranged according to different drainage objects and drainage requirements.

The utility model provides a but drainage engineering automatic sampling's remote monitoring device by China publication No. CN218411787U, including a fixed section of thick bamboo, a fixed section of thick bamboo opening sets up to the left, a fixed right side fixed connection is equipped with the dead lever outside the fixed section of thick bamboo, fixed connection is equipped with control center in the fixed section of thick bamboo, fixed interior bottom rotates to be connected and is equipped with the dwang, fixed cover is equipped with the live-rollers on the dwang, winding connection is equipped with the control line on the live-rollers, the control line runs through in a fixed section of thick bamboo setting, the control line is located a fixed outside fixed connection and is equipped with the sampling tube, fixed cover is equipped with first gear on the dwang, first gear is located the left side setting of live-rollers, fixed cover is equipped with the fourth gear on control center's the output shaft, first gear and fourth gear pass through connecting device and connect the setting. The utility model can autonomously complete the sampling operation of the water body and the descending and ascending operations of the sampling tube, and has strong practicability.

According to the technical scheme, the movable frame is connected with the fixed cylinder through the spring, the movement of the spring is unstable, the spring is attracted through the electromagnet, the movement track of the spring cannot be limited through the mode, so that the movable frame cannot be ensured to deviate in position in a mode when the movable frame moves vertically, the first gear, the second gear and the two third gears are in meshed connection, the structure of the sampling tube is unknown, and after the sampling is finished, how to seal the sampling tube is unknown.

Disclosure of Invention

The utility model aims to solve the problems that in the prior art, the movement of a spring is unstable, so that the position deviation of a moving frame cannot be guaranteed when the moving frame moves vertically, the meshing connection of a first gear, a second gear and two third gears is negatively influenced, the sampling tube structure is unknown, and after the sampling is finished, how to seal the sampling tube is unknown, and the remote monitoring device for drainage engineering sampling is provided.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the remote monitoring device for sampling in drainage engineering comprises a fixed cylinder, wherein a control center is fixedly arranged in the fixed cylinder, a driving roller is rotatably arranged in the fixed cylinder through a bearing, a movable frame for driving the driving roller to rotate positively and negatively is slidably arranged in the fixed cylinder, an air cylinder fixedly connected with the movable frame is fixedly arranged in the fixed cylinder, a first winding wheel is fixedly sleeved on the driving roller, a first traction rope is wound on the first winding wheel, a sampling box is fixedly connected on the first traction rope, a sliding groove is formed in the inner wall of the sampling box, and a pressure sensor electrically connected with the air cylinder is fixedly arranged in the sliding groove;

the sampling box is internally provided with a driving mechanism for sealing the sampling box.

Preferably, the cylinder is longitudinally arranged at the bottom end position in the fixed cylinder, and the outer wall of the fixed cylinder is fixedly connected with a fixed rod.

Preferably, the fixed cylinder is provided with a movable through hole for movably sleeving the first traction rope, and the sliding groove is longitudinally formed in the inner walls of the two sides of the sampling box.

Preferably, the driving mechanism comprises a buoyancy plate arranged in the chute, a sealing groove is formed in the bottom end position of the chute, a sealing plate fixedly connected with the buoyancy plate is arranged in the sealing groove, an installation cavity is formed in the sampling box, a second winding wheel is rotatably arranged in the installation cavity, a driven gear is fixedly connected to the second winding wheel, a driving rack which is positioned in the installation cavity and is meshed with the driven gear is fixedly connected to the buoyancy plate, a water inlet pipe is fixedly connected to the sampling box, a second traction rope is wound on the second winding wheel, and a sealing piece which extends to the water inlet pipe is fixedly connected to the lower end of the second traction rope.

Preferably, the buoyancy plate is sleeved in the sliding groove in a sliding manner, and the sealing plate is longitudinally sleeved in the sealing groove in a sliding manner.

Preferably, a guiding long hole for movably sleeving the buoyancy plate is formed in the sampling box, a movable long hole for movably sleeving the second traction rope is formed in the sampling box, and a storage groove for movably sleeving the sealing piece is formed in the inner wall of the water inlet pipe.

Compared with the prior art, the utility model has the following advantages:

1. according to the utility model, the water body can drive the buoyancy plate to vertically move upwards, the buoyancy plate drives the second winding wheel to rotate through the meshing connection of the driving rack and the driven gear, and the second winding wheel drives the sealing piece to enter the water inlet pipe through the second traction rope to seal the water inlet pipe, so that the problem that leakage occurs when the sampling box moves upwards due to the fact that the water inlet pipe still keeps an opening state after the sampling box is collected is avoided.

2. According to the utility model, the buoyancy plate presses the pressure sensor to start the air cylinder, so that the air cylinder drives the movable frame to vertically move downwards, and the movable frame is in sliding connection with the fixed cylinder, so that the relative fixation of the movement track of the movable frame is guaranteed.

Drawings

FIG. 1 is a schematic diagram of a remote monitoring device for drainage engineering sampling according to the present utility model;

FIG. 2 is a schematic diagram of a local enlarged structure of a remote monitoring device for drainage engineering sampling according to the present utility model;

fig. 3 is a schematic diagram of a connection structure of a driving rack, a driven gear and a second winding wheel of a remote monitoring device for drainage engineering sampling.

In the figure: 1. a fixed cylinder; 2. a control center; 3. a driving roller; 4. a moving frame; 5. a cylinder; 6. the first winding wheel; 7. a first traction rope; 8. a sampling box; 9. a chute; 10. a pressure sensor; 11. a buoyancy plate; 12. sealing grooves; 13. a sealing plate; 14. a mounting cavity; 15. the second winding wheel; 16. a driven gear; 17. a drive rack; 18. a water inlet pipe; 19. a second traction rope; 20. a closure.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1-3, a remote monitoring device for drainage engineering sampling, including a fixed cylinder 1, a fixed rod is fixedly connected to the outer wall of the fixed cylinder 1, a control center 2 is fixedly arranged in the fixed cylinder 1, a driving roller 3 is rotatably mounted in the fixed cylinder 1 through a bearing, a moving frame 4 for driving the driving roller 3 to rotate positively and negatively is slidably mounted in the fixed cylinder 1, and it is required to explain that: the moving frame 4 is a mature technology in the prior art, so that details are not repeated;

the inner bottom end of the fixed cylinder 1 is longitudinally and fixedly provided with a cylinder 5 fixedly connected with the movable frame 4, the model of the cylinder 5 is SCD50x100-100-LB, a first winding wheel 6 is fixedly sleeved on the driving roller 3, a first traction rope 7 is wound on the first winding wheel 6, the fixed cylinder 1 is provided with a movable through hole for movably sleeved with the first traction rope 7, and a movable space can be provided for the first traction rope 7 through the movable through hole;

the first traction rope 7 is fixedly connected with a sampling box 8, sliding grooves 9 are longitudinally formed in the inner walls of the two sides of the sampling box 8, and a pressure sensor 10 electrically connected with the air cylinder 5 is fixedly arranged in the sliding grooves 9;

a driving mechanism for sealing the sampling box 8 is arranged in the sampling box 8;

further description: the driving mechanism comprises a buoyancy plate 11 which is sleeved in the chute 9 in a sliding way, the buoyancy plate 11 can only vertically move in the chute 9 under the guiding and limiting effects of the chute 9, a guiding long hole for movably sleeved buoyancy plate 11 is formed in the sampling box 8, and a movable space can be provided for the buoyancy plate 11 through the guiding long hole;

a sealing groove 12 is formed in the bottom end position of the sliding groove 9, a sealing plate 13 fixedly connected with the buoyancy plate 11 is longitudinally sleeved in the sealing groove 12, and the sealing plate 13 and the sealing groove 12 are used for blocking the water body, so that the water body cannot enter the guide long holes or enter the upper position of the buoyancy plate 11;

the sampling box 8 is internally provided with a mounting cavity 14, a second winding wheel 15 is rotatably mounted in the mounting cavity 14, a driven gear 16 is fixedly connected to the second winding wheel 15, and a driving rack 17 which is positioned in the mounting cavity 14 and is meshed and connected with the driven gear 16 is fixedly connected to the buoyancy plate 11;

fixedly connected with inlet tube 18 on the sampling box 8, the winding has second haulage rope 19 on the second rolling wheel 15, has offered the activity slot hole that is used for the movable sleeve to establish second haulage rope 19 in the sampling box 8, second haulage rope 19 lower extreme fixedly connected with extends to the closure piece 20 in the inlet tube 18, has offered the storage tank that is used for the movable sleeve to establish closure piece 20 on the inlet tube 18 inner wall, can provide the activity space for second haulage rope 19 and closure piece 20 through storage tank and activity slot hole.

The utility model can explain its functional principle by the following modes of operation:

the control center 2 drives the driving roller 3 to rotate forward through the moving frame 4, so that the first winding wheel 6 drives the first traction rope 7 to move vertically downwards, the first traction rope 7 drives the sampling box 8 to move vertically downwards, water enters the sampling box 8 through the water inlet pipe 18, the water drives the buoyancy plate 11 to move vertically upwards, the buoyancy plate 11 drives the sealing plate 13 to move vertically upwards in the sealing groove 12, the buoyancy plate 11 drives the driving rack 17 to move vertically upwards, the driven gear 16 is driven to rotate, the driven gear 16 drives the second winding wheel 15 to rotate, the second winding wheel 15 drives the second traction rope 19 to move vertically downwards, and the second traction rope 19 drives the sealing piece 20 to enter the water inlet pipe 18 to perform sealing treatment;

the buoyancy plate 11 extrudes the pressure sensor 10, so that the air cylinder 5 drives the movable frame 4 to vertically move downwards, the control center 2 can drive the driving roller 3 to reversely rotate through the movable frame 4, the first winding wheel 6 drives the first traction rope 7 to vertically move upwards, and the first traction rope 7 drives the sampling box 8 to vertically move upwards.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. The utility model provides a remote monitoring device for drainage engineering sample, includes fixed section of thick bamboo (1), its characterized in that, fixedly is provided with control center (2) in fixed section of thick bamboo (1), install driving roller (3) through the bearing rotation in fixed section of thick bamboo (1), slidable mounting has in fixed section of thick bamboo (1) and is used for driving roller (3) to carry out moving frame (4) of corotation, fixed mounting has cylinder (5) with moving frame (4) fixed connection in fixed section of thick bamboo (1), fixed cover is equipped with first rolling wheel (6) on driving roller (3), the winding has first haulage rope (7) on first rolling wheel (6), fixedly connected with sampling box (8) on first haulage rope (7), set up spout (9) on the inner wall of sampling box (8), fixed mounting has pressure sensor (10) with cylinder (5) electric connection in spout (9).

The sampling box (8) is internally provided with a driving mechanism for sealing the sampling box (8).

2. The remote monitoring device for drainage engineering sampling according to claim 1, wherein the air cylinder (5) is longitudinally arranged at the inner bottom position of the fixed cylinder (1), and a fixed rod is fixedly connected to the outer wall of the fixed cylinder (1).

3. The remote monitoring device for drainage engineering sampling according to claim 2, wherein the fixed cylinder (1) is provided with a movable through hole for movably sleeving the first traction rope (7), and the sliding groove (9) is longitudinally formed in the inner walls of the two sides of the sampling box (8).

4. The remote monitoring device for drainage engineering sampling according to claim 1, wherein the driving mechanism comprises a buoyancy plate (11) arranged in a chute (9), a sealing groove (12) is formed in the bottom end position of the chute (9), a sealing plate (13) fixedly connected with the buoyancy plate (11) is arranged in the sealing groove (12), an installation cavity (14) is formed in the sampling box (8), a second winding wheel (15) is rotatably installed in the installation cavity (14), a driven gear (16) is fixedly connected to the second winding wheel (15), a driving rack (17) which is positioned in the installation cavity (14) and meshed with the driven gear (16) is fixedly connected to the buoyancy plate (11), a water inlet pipe (18) is fixedly connected to the sampling box (8), a second traction rope (19) is wound on the second winding wheel (15), and a sealing piece (20) extending into the water inlet pipe (18) is fixedly connected to the lower end of the second traction rope (19).

5. The remote monitoring device for drainage engineering sampling according to claim 4, wherein the buoyancy plate (11) is slidably sleeved in the chute (9), and the sealing plate (13) is longitudinally slidably sleeved in the sealing groove (12).

6. The remote monitoring device for drainage engineering sampling according to claim 4, wherein a guiding long hole for movably sleeving the buoyancy plate (11) is formed in the sampling box (8), a movable long hole for movably sleeving the second traction rope (19) is formed in the sampling box (8), and a storage groove for movably sleeving the sealing piece (20) is formed in the inner wall of the water inlet pipe (18).