CN219244729U - Rock-soil reconnaissance water level measuring mechanism - Google Patents

Abstract

The utility model relates to the field of geotechnical engineering, in particular to a geotechnical investigation water level measuring mechanism which comprises a bottom plate, wherein a connecting cylinder is arranged on the bottom plate, a first rotating rod is arranged on the connecting cylinder, a connecting frame is fixedly arranged at the top of the first rotating rod, a mounting frame is fixedly arranged on the connecting frame, a connecting roller is arranged on the mounting frame, and a traction rope is wound on the connecting roller; the connecting frame is fixedly provided with a connecting frame, the connecting frame is rotationally connected with a supporting plate, the supporting plate is connected with the connecting frame through a moving assembly, a connecting notch is formed in the supporting plate, a guide wheel is arranged in the connecting notch, a traction rope penetrates through the guide wheel to be connected with a measuring column, a water level probe is arranged at the bottom of the measuring column, a water inlet is formed in the bottom of the measuring column, and a sample storage cylinder is arranged in the measuring column.

Description

Rock-soil reconnaissance water level measuring mechanism

Technical Field

The utility model relates to the field of geotechnical engineering, in particular to a geotechnical investigation water level measuring mechanism.

Background

Geotechnical engineering solves the problems of rock mass and soil engineering, including foundation and foundation, side slope and underground engineering, and aims at finding out, analyzing and evaluating the geology, environmental characteristic and geotechnical engineering condition of the construction site and compiling the investigation file according to the requirement of the construction engineering.

In the process of reconnaissance, the geotechnical engineering needs to use a water level measuring mechanism to measure the water level of the geotechnical layer, but the current water level measuring mechanism cannot realize the sample storage treatment of the water solution, so that the use of the water level measuring mechanism is affected.

Disclosure of Invention

The utility model aims to provide a rock-soil reconnaissance water level measuring mechanism for solving the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the rock soil investigation water level measuring mechanism comprises a bottom plate, wherein a connecting cylinder is fixedly arranged on the bottom plate, a first rotating rod is arranged on the connecting cylinder, and a first driving component for driving the first rotating rod to rotate is arranged on the connecting cylinder; the top of the first rotary rod is fixedly provided with a connecting frame, the connecting frame is fixedly provided with a mounting frame, the mounting frame is provided with a connecting roller, one end of the connecting roller is provided with a second motor, the second motor is fixedly arranged on the mounting frame, and the connecting roller is wound with a traction rope; the connecting frame is fixedly installed with a connecting frame, the connecting frame is rotationally connected with a supporting plate, the supporting plate is connected with the connecting frame through a moving component, a connecting notch is formed in the supporting plate, a guide wheel is arranged inside the connecting notch, a traction rope penetrates through the guide wheel and is connected with a measuring column, a water level probe is arranged at the bottom of the measuring column, a water inlet is formed in the bottom of the measuring column, a sample storage cylinder is arranged inside the measuring column inside the water inlet, a plurality of sample storage cavities are formed in the sample storage cylinder, a connecting port is formed in the bottom of each sample storage cavity, a second rotating rod is arranged at the bottom of each sample storage cylinder, and a second driving component used for driving the second rotating rod is arranged inside the measuring column.

Preferably, the first driving assembly comprises a first motor fixedly connected with the connecting cylinder, a first gear is arranged on a motor shaft of the first motor, a second gear is connected on the first gear in a meshed mode, and the second gear is connected with the first rotating rod.

Preferably, the connecting cylinder is provided with an annular connecting groove which is in sliding connection with the connecting frame.

Preferably, the moving assembly comprises a second connecting column fixedly connected with the connecting frame, a telescopic rod is rotatably arranged on the second connecting column, a first connecting column is rotatably arranged at the end part of the telescopic rod, and the first connecting column is fixedly connected with the supporting plate.

Preferably, the second driving assembly comprises a third motor fixedly connected with the measuring column, a third gear is arranged on a motor shaft of the third motor, a fourth gear is connected to the third gear in a meshed mode, and the fourth gear is connected with the second rotating rod.

Compared with the prior art, the utility model has the beneficial effects that: according to the utility model, the first rotary rod is driven to rotate through the first driving component, the first rotary rod drives the connecting frame to rotate, and the connecting frame drives the mounting frame and the supporting plate to rotate for azimuth adjustment, so that azimuth adjustment of the adjusting measuring column and the water level probe can be realized, and the supporting plate is driven to rotate by matching with the moving component for angle adjustment, so that the rock and soil investigation water level measurement treatment of the water level probe can be facilitated; according to the utility model, the measuring column and the water level probe are driven by the traction rope to move and adjust the azimuth for water level measurement, the water level probe is moved into the water solution for rock and soil investigation, the second rotary rod is driven by the second driving component to rotate, the second rotary rod drives the sample storage cylinder to rotate, when the connecting port of the sample storage cavity is contacted with the water inlet, the water solution enters the sample storage cavity for storage through the water inlet and the connecting port, and thus the sample storage cylinder sequentially rotates to realize the connection of the connecting port of each sample storage cavity with the water inlet, and further, each sample water solution can be sequentially added into each sample storage cavity, so that the water level measurement of a measuring machine can be carried out, and meanwhile, the sampling treatment of a plurality of groups of samples can be carried out, and the rock and soil investigation treatment can be facilitated.

Drawings

Fig. 1 is a front view of a geotechnical survey water level measuring mechanism of the present utility model.

Fig. 2 is a schematic structural diagram of a soil and rock investigation water level measuring mechanism of the utility model.

Fig. 3 is an enlarged schematic view of the measuring column at a position a in the geotechnical investigation water level measuring mechanism.

Fig. 4 is a schematic three-dimensional structure of a sample storage cylinder in the geotechnical investigation water level measuring mechanism.

1. A bottom plate; 2. a roller; 3. a connecting cylinder; 4. a first rotating lever; 5. a first motor; 6. a first gear; 7. a second gear; 8. a connecting frame; 9. an annular connecting groove; 10. a mounting frame; 11. a connecting roller; 12. a second motor; 13. a traction rope; 14. a connection frame; 15. a support plate; 16. a first connection post; 17. a telescopic rod; 18. a second connection post; 19. a connection recess; 20. a guide wheel; 21. a measuring column; 22. a water level probe; 23. a water inlet; 24. a sample storage chamber; 25. a connection port; 26. a second rotating lever; 27. a third motor; 28. a third gear; 29. a fourth gear; 30. a sample storage cartridge.

Detailed Description

It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other.

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the embodiments of the present utility model will be described in detail below with reference to the accompanying drawings. However, those of ordinary skill in the art will understand that in various embodiments of the present utility model, numerous technical details have been set forth in order to provide a better understanding of the present application. However, the technical solutions claimed in the present application can be implemented without these technical details and with various changes and modifications based on the following embodiments.

The utility model will be described in detail below with reference to the drawings in connection with embodiments.

Referring to fig. 1-4, in an embodiment of the present utility model, a geotechnical investigation water level measurement mechanism includes a base plate 1, a connection cylinder 3 is fixedly installed on the base plate 1, a first rotary rod 4 is installed on the connection cylinder 3, and a first driving component for driving the first rotary rod 4 to rotate is installed on the connection cylinder 3; the top of the first rotary rod 4 is fixedly provided with a connecting frame 8, the connecting frame 8 is fixedly provided with a mounting frame 10, the mounting frame 10 is provided with a connecting roller 11, one end of the connecting roller 11 is provided with a second motor 12, the second motor 12 is fixedly arranged on the mounting frame 10, and the connecting roller 11 is wound with a traction rope 13; the connecting frame 8 is fixedly provided with a connecting frame 14, the connecting frame 14 is rotationally connected with a supporting plate 15, the supporting plate 15 is connected with the connecting frame 8 through a moving component, a connecting notch 19 is formed in the supporting plate 15, a guide wheel 20 is arranged in the connecting notch 19, a traction rope 13 passes through the guide wheel 20 to be connected with a measuring column 21, a water level probe 22 is arranged at the bottom of the measuring column 21, a water inlet 23 is formed in the bottom of the measuring column 21, a sample storage cylinder 30 is arranged in the measuring column 21 inside the water inlet 23, a plurality of sample storage cavities 24 are formed in the sample storage cylinder 30, a connecting port 25 is formed in the bottom of the sample storage cavity 24, a second rotary rod 26 is arranged at the bottom of the sample storage cylinder 30, and a second driving component for driving the second rotary rod 26 to rotate is arranged in the measuring column 21.

According to the utility model, the first driving component drives the first rotating rod 4 to drive the connecting frame 8 to rotate, the connecting frame 8 drives the measuring column 21 and the water level probe 22 to rotate, the moving component is matched to drive the supporting plate 15 to rotate, the water level probe 22 can be subjected to azimuth adjustment, the connecting roller 11 is driven to rotate by the second motor 12, the connecting roller 11 drives the traction rope 13 to move, the traction rope 13 synchronously drives the measuring column 21 to move, the azimuth of the water level probe 22 can be adjusted, the measuring column 21 moves into the aqueous solution, the second driving component drives the second rotating rod 26 to rotate, the second rotating rod 26 drives the sample storage cylinder 30 to rotate, and the aqueous solution can enter the sample storage cavity 24 to be subjected to sample collection treatment when the connecting port 25 arranged on the sample storage cylinder 30 is connected with the water inlet 23, so that the sample collection treatment of the mechanism can be facilitated.

Referring to fig. 1, in one embodiment of the present utility model, rollers 2 are installed at four corners of the bottom plate 1, and the rollers 2 are arranged to facilitate movement of a water level measuring mechanism for geotechnical investigation.

Referring to fig. 2, in an embodiment of the present utility model, the first driving assembly includes a first motor 5 fixedly connected to the connecting cylinder 3, a first gear 6 is installed on a motor shaft of the first motor 5, a second gear 7 is engaged and connected to the first gear 6, the second gear 7 is connected to the first rotating rod 4, the first motor 5 drives the first gear 6 to rotate by operating the first motor 5, and the second gear 7 can implement a rotation process for driving the first rotating rod 4.

Referring to fig. 1, in an embodiment of the present utility model, the connecting cylinder 3 is provided with an annular connecting groove 9, the annular connecting groove 9 is slidably connected with the connecting frame 8, and during the rotation of the connecting frame 8, the bottom of the connecting frame 8 rotates inside the annular connecting groove 9, so that a stable rotation process of the connecting frame 8 can be ensured.

Referring to fig. 1, in one embodiment of the present utility model, the moving assembly includes a second connecting post 18 fixedly connected to the connecting frame 8, a telescopic rod 17 is rotatably mounted on the second connecting post 18, a first connecting post 16 is rotatably mounted on an end of the telescopic rod 17, the first connecting post 16 is fixedly connected to the supporting plate 15, and the telescopic rod 17 drives the supporting plate 15 to rotate through the operation of the telescopic rod 17, so that the angle adjustment of the supporting plate 15 can be achieved.

Referring to fig. 1, in an embodiment of the present utility model, the second driving assembly includes a third motor 27 fixedly connected to the measuring column 21, a third gear 28 is installed on a motor shaft of the third motor 27, a fourth gear 29 is connected to the third gear 28 in a meshed manner, the fourth gear 29 is connected to the second rotating rod 26, the third motor 27 drives the third gear 28 to rotate by operating the third motor 27, and the fourth gear 29 can realize a rotation process of driving the second rotating rod 26.

Working principle: according to the utility model, the first motor 5 drives the first gear 6 to drive the meshed and connected second gear 7 to rotate, the second gear 7 drives the first rotary rod 4 to rotate, the first rotary rod 4 drives the connecting frame 8 to rotate under the guidance of the annular connecting groove 9, the connecting roller 11 is driven to rotate by the second motor 12, the connecting roller 11 drives the traction rope 13 to drive the measuring column 21 to move, the water level probe 22 is used for detecting the rock and soil exploration water level, when the measuring column 21 moves into the water solution, the cylinder third motor 27 drives the third gear 28 to drive the meshed and connected fourth gear 29 to rotate, the fourth gear 29 drives the second rotary rod 26 to rotate, the second rotary rod 26 synchronously drives the sample storage cylinders 30 to rotate, and when the connecting ports 25 of the sample storage cavities 24 are contacted with the water inlets 23, the water solution enters the sample storage cavities 24 to be stored through the water inlets 23 and the connecting ports 25 of the sample storage cylinders to be sequentially rotated to realize the connection of the sample storage cavities 24, and further the sequential addition of the sample aqueous solutions into the sample storage cavities 24 to be conveniently processed by the sample storage cavities 24, and the water level measurement of the measuring machine can be simultaneously processed.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. The rock soil investigation water level measuring mechanism comprises a bottom plate, and is characterized in that a connecting cylinder is fixedly arranged on the bottom plate, a first rotating rod is arranged on the connecting cylinder, and a first driving component for driving the first rotating rod to rotate is arranged on the connecting cylinder;

the top of the first rotary rod is fixedly provided with a connecting frame, the connecting frame is fixedly provided with a mounting frame, the mounting frame is provided with a connecting roller, one end of the connecting roller is provided with a second motor, the second motor is fixedly arranged on the mounting frame, and the connecting roller is wound with a traction rope;

the connecting frame is fixedly installed with a connecting frame, the connecting frame is rotationally connected with a supporting plate, the supporting plate is connected with the connecting frame through a moving component, a connecting notch is formed in the supporting plate, a guide wheel is arranged inside the connecting notch, a traction rope penetrates through the guide wheel and is connected with a measuring column, a water level probe is arranged at the bottom of the measuring column, a water inlet is formed in the bottom of the measuring column, a sample storage cylinder is arranged inside the measuring column inside the water inlet, a plurality of sample storage cavities are formed in the sample storage cylinder, a connecting port is formed in the bottom of each sample storage cavity, a second rotating rod is arranged at the bottom of each sample storage cylinder, and a second driving component used for driving the second rotating rod is arranged inside the measuring column.

2. A geotechnical survey water level measuring mechanism according to claim 1, wherein rollers are mounted at four corners of the base plate.

3. The geotechnical survey water level measurement mechanism according to claim 1, wherein the first driving assembly comprises a first motor fixedly connected with the connecting cylinder, a first gear is installed on a motor shaft of the first motor, a second gear is connected to the first gear in a meshed mode, and the second gear is connected with the first rotating rod.

4. The geotechnical survey water level measuring mechanism according to claim 1, wherein the connecting cylinder is provided with an annular connecting groove, and the annular connecting groove is in sliding connection with the connecting frame.

5. The geotechnical survey water level measuring mechanism according to claim 1, wherein the moving assembly comprises a second connecting column fixedly connected with the connecting frame, a telescopic rod is rotatably mounted on the second connecting column, a first connecting column is rotatably mounted at the end of the telescopic rod, and the first connecting column is fixedly connected with the supporting plate.

6. The geotechnical survey water level measuring mechanism according to claim 1, wherein the second driving assembly comprises a third motor fixedly connected with the measuring column, a third gear is installed on a motor shaft of the third motor, a fourth gear is connected to the third gear in a meshed mode, and the fourth gear is connected with the second rotating rod.

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