CN210834228U - Geological hydrology sampling device - Google Patents

Abstract

The utility model discloses a geological hydrology sampling device, including backup pad one, drill bit and sample cup, a backup pad upper end is provided with operating panel, it adjusts pole one to be provided with on the peripheral lateral wall of backup pad, the shaping has the locating hole on adjusting pole one or two lateral walls, it is provided with regulation pole two to adjust pole one side, it is provided with the locating pin on adjusting pole two, it is provided with the spacing ring to adjust pole one side, be provided with stop screw on the spacing ring. Has the advantages that: the utility model discloses a set up the spacing ring, adjust pole one, adjust pole two, can adjust according to outdoor topography environment, make the device steadily place, make things convenient for sample work to go on smoothly, make the practicality of device strengthen greatly, through setting up backup pad one, backup pad two, measuring tape measure, can survey in real time and excavate the degree of depth to the accuracy makes the device dig appointed exploitation degree of depth, the convenient sample.

Description

Geological hydrology sampling device

Technical Field

The utility model relates to a geological hydrology surveys technical field, concretely relates to geological hydrology sampling device.

Background

Geological hydrology is the main objective of research in engineering geological mapping and is to provide information for the research of geotechnical engineering problems and unfavorable geological phenomena related to groundwater activity, for example, when building buildings and structures are built, the permeability of the rock and soil, the buried depth of groundwater and the corrosiveness should be researched to find out the influence on the foundation building depth, foundation pit excavation and the like.

Geological hydrology acquires research data through sampling the soil of secret soil layer, consequently needs a sampling device to take a sample, and the experimental study is accomplished in the help.

At present, current sampling device lacks adjustment mechanism, and outdoor topography is mostly unsmooth, can not adjust according to outdoor environment, brings the difficulty for the outwork sample, and current sampling device lacks degree of depth testing arrangement moreover, can not directly perceivedly survey the sample and locate the degree of depth, brings certain influence for the sample.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

In order to overcome prior art not enough, now provide a geology hydrology sampling device, solved current sampling device and lacked adjustment mechanism, and outdoor topography is mostly uneven, can not adjust according to outdoor environment, brings the difficulty for the outdoor work sample, and current sampling device lacks degree of depth testing arrangement moreover, can not directly perceivedly survey the sample and locate the degree of depth, brings the problem of certain influence for the sample.

(II) technical scheme

The utility model discloses a following technical scheme realizes: the utility model provides a geological hydrology sampling device, which comprises a first support plate, a drill bit and a sampling cup, wherein the upper end of the first support plate is provided with an operation panel, a first adjusting rod is arranged on the peripheral side wall of the first support plate, positioning holes are formed on the two side walls of the first adjusting rod, a second adjusting rod is arranged on one side of the first adjusting rod, positioning pins are arranged on the second adjusting rod, a limiting ring is arranged on one side of the adjusting rod, limiting screws are arranged on the limiting ring, a support column is arranged in the limiting ring, electric push rods are arranged on two sides of the bottom end of the first support plate, a measuring tape is arranged on one side of the electric push rods, a fixed shaft is arranged on the other two sides of the bottom end of the first support plate, a second support plate is arranged at the bottom of the electric, a sample cup fixing rod is arranged on one side of the rotating rod, and the bottom of the sample cup fixing rod is provided with the sample cup.

Furthermore, the operation panel is connected with the first support plate through a bolt, the first adjusting rod is rotatably connected with the first support plate, the second adjusting rod is slidably connected with the second adjusting rod, and the positioning pin is inserted into the second adjusting rod.

According to the technical scheme, the operation control of the device is realized by controlling the on-off of a circuit in the device through the operation panel, the electric push rod is stably supported through the first support plate, the first support plate is connected through the first adjusting rod, and the position between the second adjusting rod and the first adjusting rod is conveniently adjusted through the positioning hole and the positioning pin.

Furthermore, the limiting ring is welded with the second adjusting rod, the limiting ring is connected with the supporting column in a sliding mode, and the limiting screw is connected with the limiting ring through threads.

According to the technical scheme, the limiting ring is connected with the second adjusting rod and the supporting column, the limiting ring is fixed through the limiting screw, and the supporting column provides stable support for the device.

Furthermore, the electric push rod is connected with the first support plate through a bolt, the measuring tape is connected with the first support plate through a bolt, one end of the measuring tape is connected with the second support plate through a hook, and the fixed shaft is connected with the first support plate through a bolt.

Through the technical scheme, the electric push rod pushes the second support plate to move downwards, the measuring tape measures the excavation depth, the fixed shaft provides sliding support for the second support plate,

furthermore, the second support plate is connected with the electric push rod through a bolt, and the motor is connected with the second support plate through a bolt.

Through the technical scheme, the motor is stably supported by the supporting plate II, and the rotating rod is rotated by the motor.

Further, the dwang with the motor passes through the key-type connection, the drill bit with the dwang passes through bolted connection.

Through the technical scheme, the rotating rod rotates to drive the drill bit to rotate, and then the drill bit excavates the depths of the ground bottom.

Furthermore, the sample cup fixing rod is connected with the supporting plate two-way through a bolt, and the sample cup fixing rod is connected with the sampling cup through a clamping groove.

Through the technical scheme, the sample cup fixing rod is fixed to the sample cup, and the sample cup is used for sampling soil and carrying out scientific research.

(III) advantageous effects

Compared with the prior art, the utility model, following beneficial effect has:

1. in order to solve the problems that the existing sampling device is lack of an adjusting mechanism, the outdoor terrain is mostly uneven and cannot be adjusted according to the outdoor environment, and the difficulty is brought to outdoor work sampling, the utility model discloses a limiting ring, an adjusting rod I and an adjusting rod II are arranged, so that the device can be adjusted according to the outdoor terrain environment, the device is placed stably, the sampling work is convenient to be carried out smoothly, and the practicability of the device is greatly enhanced;

2. lack degree of depth testing arrangement for solving current sampling device, can not directly perceivedly survey the sample and locate the degree of depth, bring the problem of certain influence for the sample, the utility model discloses a set up backup pad one, backup pad two, measure the tape measure, can survey the excavation depth in real time to the accuracy makes the device dig appointed exploitation degree of depth, makes things convenient for the sample.

Drawings

Fig. 1 is a schematic structural diagram of a geological and hydrological sampling device according to the present invention;

FIG. 2 is a front view of a geohydrological sampling device according to the present invention;

fig. 3 is a bottom view of the geological and hydrological sampling device of the present invention.

The reference numerals are explained below:

1. a first support plate; 2, a limiting ring; 3. a limit screw; 4. a support pillar; 5. a fixed shaft; 6. a sample cup fixing rod; 7. a sampling cup; 8. a drill bit; 9. rotating the rod; 10. a second support plate; 11. adjusting a rod I; 12. a second adjusting rod; 13. positioning pins; 14. positioning holes; 15. a motor; 16. an electric push rod; 17. an operation panel; 18. and measuring the tape measure.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

As shown in figures 1-3, a geological hydrology sampling device comprises a support plate I1, a drill 8 and a sampling cup 7, wherein an operation panel 17 is arranged at the upper end of the support plate I1, a first adjusting rod 11 is arranged on the peripheral side wall of the support plate I1, positioning holes 14 are formed in two side walls of the first adjusting rod 11, a second adjusting rod 12 is arranged on one side of the first adjusting rod 11, a positioning pin 13 is arranged on the second adjusting rod 12, a first limiting ring 2 is arranged on one side of the first adjusting rod 11, a limiting screw 3 is arranged on the limiting ring 2, a support column 4 is arranged in the limiting ring 2, electric push rods 16 are arranged on two sides of the bottom end of the support plate I1, a measuring tape 18 is arranged on one side of the electric push rods 16, a fixed shaft 5 is arranged on the other two sides of the bottom end of the, the bottom of the rotating rod 9 is provided with a drill bit 8, one side of the rotating rod 9 is provided with a sample cup fixing rod 6, and the bottom of the sample cup fixing rod 6 is provided with a sample cup 7.

As shown in fig. 1-3, the operation panel 17 is connected with the first support plate 1 through a bolt, the on-off of a circuit in the device is controlled through the operation panel 17, the operation control of the device is realized, the first adjusting rod 11 is rotatably connected with the first support plate 1, the second adjusting rod 12 is slidably connected with the second adjusting rod 12, the first support plate 1 provides stable support for the electric push rod 16, the first adjusting rod 11 is connected with the first support plate 1, the positioning pin 13 is inserted into the second adjusting rod 12, and the positioning hole 14 and the positioning pin 13 are used for conveniently adjusting the position between the second adjusting rod 12 and the first adjusting rod 11.

As shown in fig. 1-3, the limit ring 2 is welded with the second adjusting rod 12, the limit ring 2 is connected with the support column 4 in a sliding manner, the limit screw 3 is connected with the limit ring 2 through threads, the second adjusting rod 12 is connected with the support column 4 through the limit ring 2, the limit ring 2 is fixed through the limit screw 3, and the support column 4 provides stable support for the device.

As shown in fig. 1 and 2, the electric push rod 16 is connected with the first support plate 1 through a bolt, the second support plate 10 is pushed to move downwards through the electric push rod 16, the measuring tape 18 is connected with the first support plate 1 through a bolt, one end of the measuring tape 18 is connected with the second support plate 10 through a hook, the excavation depth is measured through the measuring tape 18, the fixing shaft 5 is connected with the first support plate 1 through a bolt, and the fixing shaft 5 provides sliding support for the second support plate 10.

As shown in fig. 1 and 2, the second support plate 10 is connected with the electric push rod 16 through a bolt, the second support plate 10 provides stable support for the motor 15, the motor 15 is connected with the second support plate 10 through a bolt, and the rotating rod 9 is driven to rotate through the rotation of the motor 15.

As shown in fig. 1 and 2, the rotating rod 9 is connected with the motor 15 through a key, the drill bit 8 is connected with the rotating rod 9 through a bolt, the rotating rod 9 rotates to drive the drill bit 8 to rotate, and then the drill bit 8 excavates the deep part of the ground.

As shown in fig. 1 and 2, the sample cup fixing rod 6 is connected with the second support plate 10 through a bolt, the sample cup fixing rod 6 is connected with the sample cup 7 through a clamping groove, the sample cup 7 is fixed through the sample cup fixing rod 6, and soil is sampled through the sample cup 7 to carry out scientific research.

The utility model provides a geological hydrology sampling device's theory of operation: placing a sampling device on a soil layer to be mined, adjusting the device through an adjusting limit ring 2, an adjusting rod I11 and an adjusting rod II 12 to enable the device to be more stable in the sampling process, firstly taking a positioning pin 13 out of the adjusting rod II 12, adjusting the positions of the adjusting rod I11 and the adjusting rod II 12, fixing the adjusting rod I11 and the adjusting rod II 12 through a positioning hole 14 by the positioning pin 13, then adjusting the position of the limit ring 2 along a supporting column 4 to further adjust the mining height of the device, fixing the device through a limit screw 3, controlling the on-off of a circuit of a motor 15 through an operation panel 17 to realize the start-stop of the motor 15, driving a rotating rod 9 to rotate through the rotation of the motor 15 to drive a drill bit 8 to rotate, then controlling the on-off of the circuit of an electric push rod 16 through the operation panel 17 to realize the extension and retraction of the electric push rod 16, and pressing the supporting plate I1 to, meanwhile, one end of a measuring tape 18 is driven to move, the drill bit 8 is pushed to drill into the soil layer, the excavation depth is observed through the measuring tape 18, sampling is carried out through the sampling cup 7 after the sampling position is reached, the electric push rod 16 is retracted under the control of the operation panel 17 after sampling is completed, and meanwhile, the motor 15 stops rotating to drive the drill bit 8 and the sampling cup 7 to return to the ground.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention and are not intended to limit the spirit and scope of the present invention. Without departing from the design concept of the present invention, various modifications and improvements made by the technical solution of the present invention by those skilled in the art should fall into the protection scope of the present invention, and the technical contents claimed by the present invention have been fully recorded in the claims.

Claims (7)

1. A geohydrology sampling device which characterized in that: the device comprises a first support plate (1), a drill bit (8) and a sampling cup (7), wherein an operation panel (17) is arranged at the upper end of the first support plate (1), a first adjusting rod (11) is arranged on the peripheral side wall of the first support plate (1), positioning holes (14) are formed in the two side walls of the first adjusting rod (11), a second adjusting rod (12) is arranged on one side of the first adjusting rod (11), a positioning pin (13) is arranged on the second adjusting rod (12), a limiting ring (2) is arranged on the side of the first adjusting rod (11), a limiting screw (3) is arranged on the limiting ring (2), a support column (4) is arranged in the limiting ring (2), electric push rods (16) are arranged on the two sides of the bottom end of the first support plate (1), a measuring tape (18) is arranged on one side of the electric push rods (, electric putter (16) bottom is provided with backup pad two (10), be provided with motor (15) on backup pad two (10), the transmission output of motor (15) is provided with dwang (9), dwang (9) bottom is provided with drill bit (8), dwang (9) one side is provided with appearance cup dead lever (6), appearance cup dead lever (6) bottom is provided with sample cup (7).

2. A geo-hydrological sampling device according to claim 1, wherein: the operation panel (17) is connected with the first support plate (1) through a bolt, the first adjusting rod (11) is connected with the first support plate (1) in a rotating mode, the second adjusting rod (12) is connected with the second adjusting rod (12) in a sliding mode, and the positioning pin (13) is connected with the second adjusting rod (12) in an inserting mode.

3. A geo-hydrological sampling device according to claim 1, wherein: the limiting ring (2) is welded with the second adjusting rod (12), the limiting ring (2) is in sliding connection with the supporting column (4), and the limiting screw (3) is in threaded connection with the limiting ring (2).

4. A geo-hydrological sampling device according to claim 1, wherein: the electric push rod (16) is connected with the first support plate (1) through a bolt, the measuring tape (18) is connected with the first support plate (1) through a bolt, one end of the measuring tape (18) is connected with the second support plate (10) through a hook, and the fixed shaft (5) is connected with the first support plate (1) through a bolt.

5. A geo-hydrological sampling device according to claim 1, wherein: the second support plate (10) is connected with the electric push rod (16) through a bolt, and the motor (15) is connected with the second support plate (10) through a bolt.

6. A geo-hydrological sampling device according to claim 1, wherein: dwang (9) with motor (15) pass through the key-type connection, drill bit (8) with dwang (9) pass through bolted connection.

7. A geo-hydrological sampling device according to claim 1, wherein: the sample cup fixing rod (6) is connected with the second supporting plate (10) through a bolt, and the sample cup fixing rod (6) is connected with the sample cup (7) through a clamping groove.

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