CN113375722A

CN113375722A - Geotechnical engineering intelligent monitoring system

Info

Publication number: CN113375722A
Application number: CN202110678228.6A
Authority: CN
Inventors: 陈鑫
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-06-18
Filing date: 2021-06-18
Publication date: 2021-09-10

Abstract

The invention discloses an intelligent monitoring system for geotechnical engineering, which is characterized in that: including base, drive mechanism, fixed plate, first rotor plate, embedding pole, driving plate, backup pad, ejector pad, second slider and atress board, drive mechanism sets up in the top of base, the fixed plate is fixed to be set up in the top of base, the rotation of first rotor plate sets up in the one end of fixed plate, the backup pad sets up in the top of base, this geotechnical engineering intelligent monitoring system, and practicality is strong, and accessible drive mechanism drives test probe and extends forward when detecting for test probe gets into inside the rock and detects inside the rock, and when the measuring height of needs adjustment test probe, can realize the purpose to test probe altitude mixture control through elevating system, examines time measuring when needs to the rock in different positions, and accessible rotary mechanism realizes that test probe carries out the all-round rotation and can realize.

Description

Geotechnical engineering intelligent monitoring system

Technical Field

The invention relates to the field of geotechnical engineering detection, in particular to an intelligent monitoring system for geotechnical engineering.

Background

Geotechnical engineering safety monitoring is mainly used for evaluating the conditions of main structures of railways, highways, hydraulic and hydroelectric engineering, both bank slopes, foundation foundations, soil displacement, settlement and the like through instrument observation and inspection tour, judging the safety condition of the engineering, providing management basis for supervisors or making danger early warning to prevent disaster accidents.

However, many existing geotechnical engineering detection devices have many limitations when in use, for example, the rock can not be detected in multiple directions when in use, so that the detected result is in a very single plane, and therefore the geotechnical engineering intelligent monitoring system is provided.

Disclosure of Invention

The invention aims to provide an intelligent geotechnical engineering monitoring system to solve the problem that huge labor intensity is brought to constructors because supporting rods of a wind driven generator need to be installed on the ground manually when the wind driven generator is installed in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a geotechnical engineering intelligent monitoring system, includes base, drive mechanism, fixed plate, first rotor plate, embedding pole, driving plate, backup pad, ejector pad, second slider and atress board, drive mechanism sets up in the top of base, the fixed plate is fixed to be set up in the top of base, first rotor plate is rotatory to be set up in the one end of fixed plate, the backup pad sets up in the top of base, driving plate swivelling joint is in the one end of backup pad, the embedding pole sets up perpendicularly in the surface of driving plate, the ejector pad is rotatory to be set up in the one end of first rotor plate, second slider swivelling joint is in the one end of ejector pad, the atress board is fixed to be set up in the both ends of second slider to make first rotor plate drive the second slider through the ejector pad and constitute the slip when the swing.

Preferably, the device comprises a slideway, the slideway is supported and transversely arranged on the surface of a base, a first sliding block is connected in the slideway in an embedded manner in a sliding manner, a protective frame is arranged at the top of the first sliding block, a lifting mechanism is arranged in the protective frame and positioned at the top of the first sliding block, a connecting plate is fixedly arranged at the top of the lifting mechanism, a rotating mechanism is arranged at the top of the connecting plate, a motor is arranged at the left side of the protective frame, a detection probe is movably connected at the top of the protective frame, the connecting plate is fixedly connected to the surface of the base, a threaded rod is meshed with the surface of the connecting plate, a moving block in sliding connection with the base is rotatably connected to the side surface of the threaded rod, a first moving plate is fixedly connected to one end of the moving block, a second moving plate is rotatably connected to one end of the first moving plate, and a protective cover is fixedly connected to the side surface of the second moving plate, the other end swivelling joint of second motion board about first motion board has the returning face plate, and the afterbody swivelling joint of returning face plate has the mounting panel with base fixed connection.

Preferably, the surface of the first rotating plate is provided with a sliding groove matched with the embedding rod, and the transmission plate drives the first fixing plate to surround the joint point with the fixing plate to form a swinging structure through the embedding rod when rotating.

Preferably, the surface of the supporting plate is provided with a sliding groove matched with the second sliding block, the second sliding block is embedded in the sliding groove and is in sliding connection with the sliding groove, and the second sliding block and the pushing block form a sliding structure in the sliding groove through the first rotating plate.

Preferably, elevating system includes cavity board and first fly leaf in bracing piece, the first cavity board, first gear, joint pole, second fly leaf, second gear, the second, bracing piece fixed mounting is in protective frame's top, and the first cavity board of fixed surface of bracing piece is connected with, the inner wall swivelling joint of the first cavity board has first fly leaf, and the one end swivelling joint of first fly leaf has the joint pole, the other end swivelling joint of first fly leaf has first gear, the one end swivelling joint of joint pole has the second fly leaf, and the one end swivelling joint of second fly leaf has the second gear, the both ends swivelling joint of second gear has the second cavity board with bracing piece fixed connection.

Preferably, the first gear and the second gear have the same size, and are engaged with each other, and the first movable plate drives the first gear to form a rotating structure through rotation.

Preferably, the length of the connecting rod is consistent with the distance from the circle center of the first gear to the second gear, the length of the first movable plate is consistent with the radius of the first gear, and the first gear drives the second gear to rotate so that the second hollow plate forms a sliding structure on the surface of the supporting rod.

Preferably, rotary mechanism includes transmission piece, rotatory piece, meshing dish, limiting plate, second rotor plate and rotatory piece, transmission piece fixed connection is in the top of linkage plate, and the inside swivelling joint of transmission piece has the second movable block, the side swivelling joint of second movable block has rotatory piece, the fixed surface of rotatory piece is connected with the meshing dish, and the surface laminating of meshing dish have with protective frame fixed connection's limiting plate, the inner wall swivelling joint of rotatory piece has first movable block, and the side swivelling joint of first movable block has the second rotor plate.

Preferably, limiting plate inside be provided with meshing dish assorted station groove, and inside the recess that meshing dish embedding limiting plate inside set up and rather than swing joint, rotatory piece makes the second rotor plate drive test probe constitution revolution mechanic through the rotation.

Compared with the prior art, the invention has the beneficial effects that:

1. this geotechnical engineering intelligent monitoring system, through setting up drive mechanism, when needs control test probe and survey time measuring to the rock depths, at first rotatory through control driving plate, driving plate can drive the embedding pole rotatory with self fixed connection afterwards, because the embedding pole embedding is in the inside of first rotor plate, when the embedding pole is rotatory, can slide in the recess that first rotor plate surface set up, when sliding, can drive first rotor plate and rotate along linking department with the backup pad, when first rotor plate is rotatory, can drive the second slider through the ejector pad and slide in the spout that the backup pad top set up, the second slider can drive the atress board with self fixed connection afterwards and constitute the push structure, make it drive test probe through the protection frame and constitute sliding structure, go deep into the rock depths and survey.

2. This geotechnical engineering intelligent monitoring system, through setting up elevating system, at first control first fly leaf is around to get to link up the point with first well hollow plate and rotate, when it is rotatory, can drive the first gear with self swivelling joint and constitute revolution mechanic, when first gear is rotatory back, can drive the second gear and rotate, link up the pole afterwards can drive through rotatory second gear and second fly leaf and constitute elevation structure with bracing piece sliding connection's second well hollow plate, when the hollow plate goes up and down in the second, can drive the test probe through linking up the board and constitute elevation structure, reach the purpose that detects the rock of co-altitude with this.

3. This geotechnical engineering intelligent monitoring system, through setting up rotary mechanism, when the motor drives the transmission piece rotatory, the transmission piece can drive then rotatory with self swivelling joint's second movable block, the second movable block can drive rotatory with self swivelling joint's rotatory piece afterwards, rotatory back of piece, can drive the station inslot internal rotation that sets up at the limiting plate with self fixed connection's meshing dish, make the limiting plate play limiting displacement to the rotation piece, when rotatory piece is rotatory, can drive first movable block and constitute revolution mechanic, after first movable block is rotatory, can drive through the second rotor plate with self swivelling joint and constitute all-round revolution mechanic with second rotor plate fixed connection's test probe, make test probe can detect the rock in different position.

4. This geotechnical engineering intelligent monitoring system, practicality is strong, accessible drive mechanism drives test probe and extends forward when detecting for test probe gets into the inside rock that detects, and when the measuring height of needs adjustment test probe, can realize the purpose to test probe altitude mixture control through elevating system, when needs examine the rock in different position time measuring, accessible rotary mechanism realizes that test probe carries out the all around rotation and can realize.

Drawings

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

FIG. 2 is a schematic three-dimensional structure of the present invention;

FIG. 3 is a schematic view of the transmission mechanism of the present invention;

FIG. 4 is a schematic view of the lift mechanism of the present invention;

FIG. 5 is a schematic view of a rotating mechanism according to the present invention;

FIG. 6 is a schematic view of a rotating mechanism according to the present invention;

fig. 7 is a partially enlarged schematic view of the present invention.

In the figure: 1. a base; 2. a slideway; 3. a transmission mechanism; 301. a fixing plate; 302. a first rotating plate; 303. an embedded rod; 304. a drive plate; 305. a support plate; 306. a push block; 307. a second slider; 308. a stress plate; 4. a first slider; 5. a protective frame; 6. a lifting mechanism; 601. a support bar; 602. a first hollow plate; 603. a first gear; 604. a connecting rod; 605. a second movable plate; 606. a second gear; 607. a second hollow plate; 608. a first movable plate; 7. a connector tile; 8. a rotation mechanism; 801. a transmission block; 802. rotating the block; 803. an engaging disk; 804. a limiting plate; 805. a second rotating plate; 806. a first movable block; 807. a second movable block; 9. a motor; 10. detecting a probe; 11. an engaging plate; 12. a threaded rod; 13. a moving block; 14. a first motion plate; 15. a second motion plate; 16. a protective cover; 17. a turnover plate; 18. and (7) mounting the plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 7, in an embodiment of the present invention, an intelligent monitoring system for geotechnical engineering is characterized in that: the automatic rotating device comprises a base 1, a transmission mechanism 3, a fixed plate 301, a first rotating plate 302, an embedded rod 303, a transmission plate 304, a supporting plate 305, a pushing block 306, a second sliding block 307 and a stress plate 308, wherein the transmission mechanism 3 is arranged at the top of the base 1, the fixed plate 301 is fixedly arranged at the top of the base 1, the first rotating plate 302 is rotatably arranged at one end of the fixed plate 301, the supporting plate 305 is arranged at the top of the base 1, the transmission plate 304 is rotatably connected to one end of the supporting plate 305, the embedded rod 303 is vertically arranged on the surface of the transmission plate 304, the pushing block 306 is rotatably arranged at one end of the first rotating plate 302, the second sliding block 307 is rotatably connected to one end of the pushing block 306, and the stress plate 308 is fixedly arranged at two ends of the second sliding block 307, so that the first rotating plate 302 drives the second sliding block 307 to slide through the pushing block 306 when swinging.

The device comprises a slideway 2, the slideway 2 is supported and transversely arranged on the surface of a base 1, a first sliding block 4 is embedded in the slideway 2 and is in sliding connection with the first sliding block 4, a protective frame 5 is arranged at the top of the first sliding block 4, a lifting mechanism 6 is arranged in the protective frame 5 and positioned at the top of the first sliding block 4, a connecting plate 7 is fixedly arranged at the top of the lifting mechanism 6, a rotating mechanism 8 is arranged at the top of the connecting plate 7, a motor 9 is arranged at the left side of the protective frame 5, a detection probe 10 is movably connected at the top of the protective frame 5, an engaging plate 11 is fixedly connected to the surface of the base 1, a threaded rod 12 is engaged with the surface of the engaging plate 11, a moving block 13 in sliding connection with the base 1 is rotatably connected to the side surface of the threaded rod 12, a first moving plate 14 is fixedly connected to one end of the moving block 13, and a second moving plate 15 is rotatably connected to one end of the first moving plate 14, and the side fixedly connected with protection casing 16 of second moving plate 15, second moving plate 15 has returning face plate 17 about the other end swivelling joint of first moving plate 14, and the afterbody swivelling joint of returning face plate 17 has mounting panel 18 with base 1 fixed connection, through setting up first slider 4, when first slider 4 slides in slide 2 is inside, can drive test probe 10 and remove about for test probe 10 gos deep into the rock and gos deep into and surveys.

The surface of the first rotating plate 302 is provided with a sliding groove matched with the embedded rod 303, and the transmission plate 304 drives the first fixing plate 301 to form a swinging structure around a connection point with the fixing plate 301 through the embedded rod 303 when rotating, by arranging the first rotating plate 302, because the embedded rod 303 is embedded in the first rotating plate 302, when the embedded rod 303 rotates, the first rotating plate 302 can slide in a groove arranged on the surface of the first rotating plate 302, and when the first rotating plate 302 slides, the first rotating plate 302 can be driven to rotate along the connection position with the supporting plate 305, so that power is provided for the sliding of the second sliding block 307.

The surface of the supporting plate 305 is provided with a sliding groove matched with the second sliding block 307, the second sliding block 307 is embedded in the sliding groove and is in sliding connection with the sliding groove, the second sliding block 307 forms a sliding structure in the sliding groove through the first rotating plate 302 and the pushing block 306, by arranging the second sliding block 307, when the first rotating plate 302 rotates, the pushing block 306 drives the second sliding block 307 to slide in the sliding groove arranged at the top of the supporting plate 305, and then the second sliding block 307 drives the stress plate 308 fixedly connected with the second sliding block 307 to form a pushing structure, so that the stress plate drives the detection probe 10 to form a sliding structure through the protection frame, and the detection probe penetrates into rock to be deeply detected.

The lifting mechanism 6 comprises a supporting rod 601, a first hollow plate 602, a first gear 603, a connecting rod 604, a second movable plate 605, a second gear 606, a second hollow plate 607 and a first movable plate 608, the supporting rod 601 is fixedly mounted on the top of the protective frame 5, the surface of the supporting rod 601 is fixedly connected with the first hollow plate 602, the inner wall of the first hollow plate 602 is rotatably connected with the first movable plate 608, one end of the first movable plate 608 is rotatably connected with the connecting rod 604, the other end of the first movable plate 608 is rotatably connected with the first gear 603, one end of the connecting rod 604 is rotatably connected with the second movable plate 605, one end of the second movable plate 605 is rotatably connected with the second gear 606, the two ends of the second gear 606 are rotatably connected with the second hollow plate 607 fixedly connected with the supporting rod 601, by arranging the lifting mechanism 6, when the first movable plate 608 rotates, the first gear 603 rotatably connected with itself is driven to form a rotating structure, when the first gear 603 rotates, the second gear 606 is driven to rotate, then the connecting rod 604 drives the second hollow plate 607 slidably connected to the supporting rod 601 through the rotating second gear 606 and the second movable plate 605 to form a lifting structure, and when the second hollow plate 607 lifts, the connecting plate 7 drives the detecting probe 10 to form a lifting structure, so as to adjust the detecting probe 10 to a proper height for detecting the rock.

The first gear 603 and the second gear 606 have the same size, and the first gear 603 and the second gear 606 are engaged with each other, the first movable plate 608 rotates to drive the first gear 603 to form a rotating structure, by providing the first gear 603, when the first gear 603 rotates, the second gear 606 is driven to rotate, and then the connecting rod 604 drives the second hollow plate 607 slidably connected to the supporting rod 601 through the rotating second gear 606 and the second movable plate 605 to form a lifting structure.

The length of the connecting rod 604 is consistent with the distance from the circle center of the first gear 603 to the second gear 606, the length of the first movable plate 608 and the second movable plate 605 is consistent with the radius of the first gear 603, and the first gear 603 drives the second gear 606 to rotate so that the second hollow plate 607 forms a sliding structure on the surface of the supporting rod 601, and by arranging the second hollow plate 607, when the second hollow plate 607 goes up and down, the connecting plate 7 can drive the detection probe 10 to form a lifting structure, so that the detection probe 10 can be adjusted to a proper height to detect the rock.

The rotating mechanism 8 comprises a transmission block 801, a rotating block 802, an engaging disc 803, a limiting plate 804, a second rotating plate 805 and a rotating block 802, the transmission block 801 is fixedly connected to the top of the connecting plate 7, the transmission block 801 is internally and rotatably connected with a second movable block 807, the side surface of the second movable block 807 is rotatably connected with the rotating block 802, the surface of the rotating block 802 is fixedly connected with the engaging disc 803, the surface of the engaging disc 803 is attached with the limiting plate 804 fixedly connected with the protective frame 5, the inner wall of the rotating block 802 is rotatably connected with a first movable block 806, the side surface of the first movable block 806 is rotatably connected with a second rotating plate 805, by arranging the rotating mechanism 8, when the transmission block 801 rotates, the transmission block 801 can further drive the second movable block 807 which is rotatably connected with itself to rotate, then the second movable block 807 can drive the rotating block 802 which is rotatably connected with itself to rotate, after the rotating block 802 rotates, can drive the station inslot internal rotation that sets up at limiting plate 804 with self fixed connection's meshing dish 803 for limiting plate 804 plays limiting displacement to rotatory piece 802, when rotatory piece 802 is rotatory, can drive first movable block 806 and constitute revolution mechanic, after first movable block 806 is rotatory, can drive through the second rotor plate 805 with self swivelling connection and constitute all-round revolution mechanic with second rotor plate 805 fixed connection's measuring probe 10, make measuring probe 10 can detect the rock in different position.

Limiting plate 804 is inside to be provided with meshing dish 803 assorted station groove, and meshing dish 803 imbeds the inside recess that sets up of limiting plate 804 inside and rather than swing joint, rotatory piece 802 makes second rotor plate 805 drive test probe 10 through rotatory and constitutes revolution mechanic, through setting up limiting plate 804, rotatory piece 802 is rotatory back, can drive the station inslot rotation of setting up at limiting plate 804 with self fixed connection's meshing dish 803 for limiting plate 804 plays limiting displacement to rotatory piece 802.

The working principle of the invention is as follows: when the geotechnical engineering intelligent monitoring system is used, a first movable plate 608 is firstly controlled to rotate around a joint point with a first hollow plate 602, when the geotechnical engineering intelligent monitoring system rotates, a first gear 603 rotationally connected with the geotechnical engineering intelligent monitoring system is driven to form a rotating structure, when the first gear 603 rotates, a second gear 606 is driven to rotate, then a second gear 606 and a second movable plate 605 which rotate drive a second hollow plate 607 slidably connected with a support rod 601 to form a lifting structure, when the second hollow plate 607 lifts, a joint plate 7 drives a detection probe 10 to form a lifting structure, so that the detection probe 10 is adjusted to be at a proper height to detect rocks, then the rocks are detected through the detection probe 10, when the motor 9 drives a transmission block 801 to rotate for rocks in different directions, the transmission block 801 drives a second movable block 807 rotationally connected with the geotechnical engineering intelligent monitoring system to rotate, then the second movable block 807 will drive the rotating block 802 connected with itself to rotate, after the rotating block 802 rotates, the engaging disc 803 connected with itself to rotate in the station slot set inside the limiting plate 804, so that the limiting plate 804 can limit the rotating block 802, when the rotating block 802 rotates, the first movable block 806 will be driven to form a rotating structure, after the first movable block 806 rotates, the second rotating plate 805 connected with itself to rotate will drive the detecting probe 10 connected with the second rotating plate 805 to form an omnibearing rotating structure, so that the detecting probe 10 can detect rocks in different directions, when detecting the gap of rocks, firstly, the driving plate 304 is controlled to rotate, then the driving plate 304 will drive the embedding rod 303 connected with itself to rotate, because the embedding rod 303 is embedded inside the first rotating plate 302, when the embedded rod 303 rotates, the embedded rod slides in a groove formed in the surface of the first rotating plate 302, when the embedded rod slides, the first rotating plate 302 is driven to rotate along the joint with the supporting plate 305, when the first rotating plate 302 rotates, the pushing block 306 drives the second sliding block 307 to slide in a sliding groove formed in the top of the supporting plate 305, then the second sliding block 307 drives the stress plate 308 fixedly connected with the second sliding block 307 to form a pushing structure, so that the stress plate drives the detection probe 10 to form a sliding structure through the protection frame, the deep rock is deeply detected, when the detection probe 10 needs to be protected, the threaded rod 12 can be rotated to enable the threaded rod 12 to push the moving block 13 to move towards the left side on the surface of the base 1, when the stress plate moves towards the left side, the stress plate can cooperate with the turning plate 17 to drive the protection cover 16 to rotate towards the right side, so that the detection probe 10 is covered by the protection cover 16, the detection probe 10 is protected.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The utility model provides a geotechnical engineering intelligent monitoring system which characterized in that: the novel rotary table comprises a base (1), a transmission mechanism (3), a fixed plate (301), a first rotary plate (302), an embedded rod (303), a transmission plate (304), a support plate (305), a push block (306), a second sliding block (307) and a stress plate (308), wherein the transmission mechanism (3) is arranged at the top of the base (1), the fixed plate (301) is fixedly arranged at the top of the base (1), the first rotary plate (302) is rotatably arranged at one end of the fixed plate (301), the support plate (305) is arranged at the top of the base (1), the transmission plate (304) is rotatably connected to one end of the support plate (305), the embedded rod (303) is vertically arranged on the surface of the transmission plate (304), the push block (306) is rotatably arranged at one end of the first rotary plate (302), the second sliding block (307) is rotatably connected to one end of the push block (306), and the stress plate (308) is fixedly arranged at two ends of the second sliding block (307), so that the first rotating plate (302) drives the second sliding block (307) to slide through the pushing block (306) when swinging.

2. The geotechnical engineering intelligent monitoring system according to claim 1, wherein: comprises a slideway (2), the slideway (2) is supported and transversely arranged on the surface of a base (1), a first sliding block (4) is embedded in the slideway (2) in a sliding manner, a protective frame (5) is arranged at the top of the first sliding block (4), a lifting mechanism (6) is arranged in the protective frame (5) and positioned at the top of the first sliding block (4), a connecting plate (7) is fixedly arranged at the top of the lifting mechanism (6), a rotating mechanism (8) is arranged at the top of the connecting plate (7), a motor (9) is arranged on the left side of the protective frame (5), a detection probe (10) is movably connected to the top of the protective frame (5), an engaging plate (11) is fixedly connected to the surface of the base (1), a threaded rod (12) is engaged with the surface of the engaging plate (11), a moving block (13) which is in sliding connection with the base (1) is rotatably connected to the side surface of the threaded rod (12), and one end of the moving block (13) is fixedly connected with a first moving plate (14), one end of the first moving plate (14) is rotatably connected with a second moving plate (15), the side face of the second moving plate (15) is fixedly connected with a protective cover (16), the other end of the second moving plate (15) relative to the first moving plate (14) is rotatably connected with a turnover plate (17), and the tail part of the turnover plate (17) is rotatably connected with a mounting plate (18) fixedly connected with the base (1).

3. The geotechnical engineering intelligent monitoring system according to claim 1, wherein: the surface of the first rotating plate (302) is provided with a sliding groove matched with the embedding rod (303), and the transmission plate (304) drives the first fixing plate (301) to surround the connecting point with the fixing plate (301) to form a swinging structure through the embedding rod (303) when rotating.

4. The geotechnical engineering intelligent monitoring system according to claim 1, wherein: the surface of the supporting plate (305) is provided with a sliding groove matched with the second sliding block (307), the second sliding block (307) is embedded into the sliding groove and is in sliding connection with the sliding groove, and the second sliding block (307) forms a sliding structure in the sliding groove through the first rotating plate (302) and the pushing block (306).

5. The geotechnical engineering intelligent monitoring system according to claim 1, wherein: the lifting mechanism (6) comprises a supporting rod (601), a first hollow plate (602), a first gear (603), a connecting rod (604), a second movable plate (605), a second gear (606), a second hollow plate (607) and a first movable plate (608), wherein the supporting rod (601) is fixedly mounted at the top of the protective frame (5), the surface of the supporting rod (601) is fixedly connected with the first hollow plate (602), the inner wall of the first hollow plate (602) is rotatably connected with the first movable plate (608), one end of the first movable plate (608) is rotatably connected with the connecting rod (604), the other end of the first movable plate (608) is rotatably connected with the first gear (603), one end of the connecting rod (604) is rotatably connected with the second movable plate (605), one end of the second movable plate (605) is rotatably connected with the second gear (606), and two ends of the second gear (606) are rotatably connected with the second hollow plate (607) fixedly connected with the supporting rod (601) ).

6. The geotechnical engineering intelligent monitoring system according to claim 5, wherein: the first gear (603) and the second gear (606) are identical in size, the first gear (603) and the second gear (606) are in a mutually meshed state, and the first movable plate (608) drives the first gear (603) through rotation to form a rotating structure.

7. The geotechnical engineering intelligent monitoring system according to claim 5, wherein: the length of the connecting rod (604) is consistent with the distance from the circle center of the first gear (603) to the second gear (606), the lengths of the first movable plate (608) and the second movable plate (605) are consistent with the radius of the first gear (603), and the first gear (603) drives the second gear (606) to rotate so that the second hollow plate (607) forms a sliding structure on the surface of the supporting rod (601).

8. The geotechnical engineering intelligent monitoring system according to claim 1, wherein: rotary mechanism (8) include transmission piece (801), rotatory piece (802), meshing dish (803), limiting plate (804) and second rotor plate (805), transmission piece (801) fixed connection is in the top of linking up fishplate bar (7), and the inside swivelling joint of transmission piece (801) has second movable block (807), the side swivelling joint of second movable block (807) has rotatory piece (802), the fixed surface of rotatory piece (802) is connected with meshing dish (803), and the surface laminating of meshing dish (803) have with protective frame (5) fixed connection's limiting plate (804), the inner wall swivelling joint of rotatory piece (802) has first movable block (806), and the side swivelling joint of first movable block (806) has second rotor plate (805).

9. The geotechnical engineering intelligent monitoring system according to claim 8, wherein: limiting plate (804) inside be provided with meshing dish (803) assorted station groove, and meshing dish (803) imbed limiting plate (804) inside the recess that sets up and rather than swing joint, rotatory piece (802) make second rotor plate (805) drive test probe (10) through rotatory and constitute revolution mechanic.