CN213633103U - Engineering geology reconnaissance water-under test automatic checkout device - Google Patents

Abstract

The utility model discloses an engineering geology reconnaissance pressurized-water experiment automatic checkout device, including ground and first tight pulley, the top on ground is provided with the base, the right side of first tight pulley is provided with the second tight pulley, the detection case is installed on the right side of second tight pulley, the hinge is installed on the right side of the door body, the inside of stand is provided with the bolt, the inside of activity post is provided with the locating hole, the connecting rod is installed on telescopic cylinder's right side, the right side of probe is provided with the investigation hole, the internally mounted of the door body has the treater, the display screen is installed to the top of transmission port, and the top of display screen is provided with the spirit level. This engineering geology reconnaissance pressurized-water experiment automatic checkout device is provided with movable post for can carry out the lift adjustment of height, and be provided with telescopic cylinder, make the probe can survey the hole of different diameters, the setting up of spirit level makes this device can steadily place simultaneously, can not influence the exploration data.

Description

Engineering geology reconnaissance water-under test automatic checkout device

Technical Field

The utility model relates to an engineering geology reconnaissance and technical field specifically are an engineering geology reconnaissance pressurized-water experiment automatic checkout device.

Background

The geological exploration field is based on the natural science and the earth science as theoretical basis, engineering problems related to geological survey, general survey and exploration of mineral resources, geological structure of major engineering and geological background are taken as main objects, geology, geophysical and geochemical technologies, mathematical geological methods, remote sensing technologies, testing technologies, computer technologies and the like are taken as means, and in geological exploration, a water-pressing experiment is an essential experiment and needs to detect parameters such as water seepage and the like.

The existing automatic detection device for the pressurized water experiment on the market has the problems that the device cannot be adjusted in height and cannot detect parameters with different heights in the working process, a probe of the device does not have a telescopic function, holes with different diameters cannot be detected, the device is not practical, and the device is unstable and easy to incline when placed.

Aiming at the problems, innovative design is urgently needed on the basis of the original automatic detection device for the engineering geological exploration water-pressurizing experiment, and therefore the automatic detection device for the engineering geological exploration water-pressurizing experiment is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an engineering geology reconnaissance pressurized-water experiment automatic checkout device to there is the device in the use of working to solve the current pressurized-water experiment automatic checkout device on the market that proposes in the above-mentioned background art and can not height-adjusting, can not detect the parameter of co-altitude, and the probe of device does not possess flexible function, can not detect the hole of different diameters, has the device impracticality very simultaneously, leads to unstability when placing easily, the problem of easy slope. Therefore, the automatic detection device for the water-pressing experiment in engineering geological exploration is designed.

In order to achieve the above object, the utility model provides a following technical scheme: an automatic detection device for a water-pressing experiment in engineering geological exploration comprises a ground and a first fixed wheel, wherein a base is arranged above the ground, a connecting beam is arranged on the right side of the base, a second fixed wheel is arranged on the right side of the first fixed wheel, the first fixed wheel is positioned above the base, a detection box is arranged on the right side of the second fixed wheel, a door body is arranged inside the detection box, a hinge is arranged on the right side of the door body, an upright post is arranged below the hinge, a bolt is arranged inside the upright post, a movable post is arranged below the bolt, a positioning hole is arranged inside the movable post, a telescopic cylinder is arranged below the positioning hole, a connecting rod is arranged on the right side of the telescopic cylinder, a probe is arranged on the right side of the connecting rod, a exploration hole is arranged on the right side of the probe, a processor is arranged inside the door body, and the right side of the processor is provided with a transmission port, a display screen is arranged above the transmission port, and a level gauge is arranged above the display screen.

Preferably, the detection box forms a rotating structure with the first fixed wheel through the cooperation between the second fixed wheel and the connecting beam, and the second fixed wheel, the connecting beam and the first fixed wheel are symmetrically distributed about the vertical center line of the detection box.

Preferably, the door body forms a turnover structure through the matching between the hinge and the detection box, and the door body is connected with the detection box through the hinge.

Preferably, the movable column forms a lifting structure through the matching between the upright column and the detection box, and the outer surface of the movable column is attached to the inner surface of the upright column.

Preferably, the positioning holes are fixedly connected with the movable columns, and the positioning holes are distributed at equal intervals relative to the vertical center line of the movable columns.

Preferably, the probe and the telescopic cylinder form a translation structure in front of the probe and the telescopic cylinder, and the probe and the connecting rod form a detachable structure in front of the probe and the connecting rod.

Compared with the prior art, the beneficial effects of the utility model are that:

1. this engineering geology reconnaissance pressurized-water experiment automatic checkout device is provided with movable post, through installing the movable post in the stand below, has improved the practicality of this device greatly for can go up and down, the device just can survey the hole of co-altitude not like this, has avoided the device can not height-adjusting, can not detect the condition of the parameter of co-altitude not.

2. This engineering geology reconnaissance pressurized-water experiment automatic checkout device is provided with telescopic cylinder, through installing at the left telescopic cylinder of connecting rod, has improved the compatibility of this device greatly, and telescopic cylinder can make this device survey the hole of different diameters, provides very big convenience for user's exploration, has avoided the probe not to possess flexible function, can not detect the condition in the hole of different diameters.

3. This engineering geology reconnaissance pressurized-water experiment automatic checkout device is provided with the spirit level, through installing the spirit level in the detection case inside for this device has had the multifunctionalization, and the user comes to carry out the level (l) ing to the device through the bubble activity of watching in the spirit level, makes the result of exploration accurate more like this, and is not steady when having avoided the device to place, and easy slope leads to the unsafe condition of exploration data.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic side view of the present invention;

fig. 3 is the schematic diagram of the internal structure of the detection box of the present invention.

In the figure: 1. a ground surface; 2. a base; 3. a first fixed wheel; 4. a connecting beam; 5. a second fixed wheel; 6. a detection box; 7. a door body; 8. a hinge; 9. a column; 10. a bolt; 11. a movable post; 12. positioning holes; 13. a telescopic cylinder; 14. a connecting rod; 15. a probe; 16. exploratory holes; 17. a processor; 18. a transmission port; 19. a display screen; 20. a level gauge.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: an automatic detection device for a water-pressing experiment in engineering geological investigation comprises a ground 1 and a first fixed wheel 3, wherein a base 2 is arranged above the ground 1, a connecting beam 4 is arranged on the right side of the base 2, a second fixed wheel 5 is arranged on the right side of the first fixed wheel 3, the first fixed wheel 3 is positioned above the base 2, a detection box 6 is arranged on the right side of the second fixed wheel 5, a door body 7 is arranged in the detection box 6, the detection box 6 and the first fixed wheel 3 form a rotating structure through the matching between the second fixed wheel 5 and the connecting beam 4, the second fixed wheel 5, the connecting beam 4 and the first fixed wheel 3 are symmetrically distributed about the vertical central line of the detection box 6, the rotating structure enables the detection box 6 to be rotationally adjusted and is used for adjusting the horizontal position of the detection box 6, the stacking distribution can enable the detection box to be more stable, a hinge 8 is arranged on the right side of the door body 7, and the lower part of the hinge 8 is provided with a column 9, the door body 7 forms a turnover structure through the matching between the hinge 8 and the detection box 6, the door body 7 and the detection box 6 are connected through a hinge, the door body 7 of the turnover structure can be freely opened and closed, the hinge connection has the advantages of silence and maximized stroke, the inner part of the column 9 is provided with a bolt 10, the lower part of the bolt 10 is provided with a movable column 11, the movable column 11 forms a lifting structure through the matching between the column 9 and the detection box 6, the outer surface of the movable column 11 is mutually attached to the inner surface of the column 9, the movable column 11 is arranged on the device, the practicability of the device is greatly improved, the lifting can be carried out, thus the device can survey holes with different heights, the inner part of the movable column 11 is provided with a positioning hole 12, and a telescopic cylinder 13 is arranged below the positioning hole 12, the positioning holes 12 are fixedly connected with the movable columns 11, the positioning holes 12 are equidistantly distributed about the vertical central line of the movable columns 11, the positioning holes 12 play a good fixing role for the movable columns 11, the equidistant distribution design enables adjustment of different heights to be carried out, the connecting rod 14 is installed on the right side of the telescopic cylinder 13, the probe 15 is installed on the right side of the connecting rod 14, the probe 15 forms a translation structure with the front of the telescopic cylinder 13 through the connecting rod 14, the probe 15 forms a detachable structure with the front of the connecting rod 14, the telescopic cylinder 13 is arranged on the device, the practicability of the device is greatly improved, the telescopic cylinder 13 can enable the device to detect holes with different diameters, the right side of the probe 15 is provided with an exploration hole 16, the inside of the door body 7 is provided with a processor 17, the right side of the processor 17 is provided with a transmission port 18, and a display screen 19 is installed above the, and a level gauge 20 is provided above the display screen 19.

The working principle is as follows: the automatic detection device for the water-pressing experiment comprises the steps of firstly placing a base 2 of the device on the ground 1, then rotating a bolt 10 to loosen the bolt, moving a movable column 11 into an upright column 9, rotating the bolt 10 when the bolt is adjusted to a proper height, enabling the bolt 10 to be matched with a positioning hole 12 on the movable column 11, adjusting the height to be fixed, then placing the upright column 9 into an exploration hole 16, driving a probe 15 on a connecting rod 14 to move in a translation mode through a telescopic cylinder 13, enabling the probe 15 to touch the inner wall of the exploration hole 16, opening a door body 7 through a hinge 8, arranging a level gauge 20 inside a detection box 6, enabling a user to observe bubbles on the level gauge 20 and slightly rotating a first fixed wheel 3 and a second fixed wheel 5 to enable the detection box 6 to be kept in a horizontal state, enabling a connecting beam 4 to play a role in supporting and stabilizing, and installing the device, the detection can be carried out, the probe 15 transmits the detection data to the processor 17, the processor 17 is of the type CeleronD365, and finally, a user checks the detection data through the display screen 19 and is provided with a transmission port 18 which can lead the data out, so that the use process of the automatic detection device for the water pressurizing experiment is realized.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides an engineering geology reconnaissance pressurized-water experiment automatic checkout device, includes ground (1) and first tight pulley (3), its characterized in that: the detection device is characterized in that a base (2) is arranged above the ground (1), a connecting beam (4) is installed on the right side of the base (2), a second fixed wheel (5) is arranged on the right side of the first fixed wheel (3), the first fixed wheel (3) is located above the base (2), a detection box (6) is installed on the right side of the second fixed wheel (5), a door body (7) is arranged inside the detection box (6), a hinge (8) is installed on the right side of the door body (7), an upright column (9) is arranged below the hinge (8), a bolt (10) is arranged inside the upright column (9), a movable column (11) is arranged below the bolt (10), a positioning hole (12) is formed inside the movable column (11), a telescopic cylinder (13) is installed below the positioning hole (12), a connecting rod (14) is installed on the right side of the telescopic cylinder (13), and probe (15) are installed on the right side of connecting rod (14), the right side of probe (15) is provided with exploration hole (16), the internally mounted of door body (7) has treater (17), and transmission port (18) are installed on the right side of treater (17), display screen (19) are installed to the top of transmission port (18), and the top of display screen (19) is provided with spirit level (20).

2. The automatic detection device for the engineering geological exploration water-pressure experiment of claim 1, which is characterized in that: the detection box (6) forms a rotating structure with the first fixed wheel (3) through the matching between the second fixed wheel (5) and the connecting beam (4), and the vertical central lines of the detection box (6) are symmetrically distributed among the second fixed wheel (5), the connecting beam (4) and the first fixed wheel (3).

3. The automatic detection device for the engineering geological exploration water-pressure experiment of claim 1, which is characterized in that: the door body (7) is matched with the detection box (6) through the hinge (8) to form a turnover structure, and the door body (7) is connected with the detection box (6) through a hinge.

4. The automatic detection device for the engineering geological exploration water-pressure experiment of claim 1, which is characterized in that: the movable column (11) forms a lifting structure through the matching between the upright column (9) and the detection box (6), and the outer surface of the movable column (11) is mutually attached to the inner surface of the upright column (9).

5. The automatic detection device for the engineering geological exploration water-pressure experiment of claim 1, which is characterized in that: the positioning holes (12) are fixedly connected with the movable columns (11), and the positioning holes (12) are distributed at equal intervals relative to the vertical center line of the movable columns (11).

6. The automatic detection device for the engineering geological exploration water-pressure experiment of claim 1, which is characterized in that: the probe (15) and the telescopic cylinder (13) form a translation structure in front of the connecting rod (14), and the probe (15) and the connecting rod (14) form a detachable structure in front of the connecting rod.

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