CN117167631B - GNSS displacement monitor locating support with adjustable - Google Patents

Abstract

The invention discloses an adjustable GNSS displacement monitor positioning bracket, which relates to the technical field of monitor positioning brackets, and comprises a stabilizing mechanism, a positioning mechanism and a positioning mechanism, wherein the stabilizing mechanism is arranged at the lower position of a fixed plate, the bottom of the fixed plate is in close contact with the ground, and the stabilizing mechanism is buried at the lower position of the ground and is used for improving the connection stability with the ground; the device comprises a bottom shell fixedly connected to the lower position of the wall surface of the mechanism, and an anchor assembly is connected to the inner side surface of the bottom shell through threads. This GNSS displacement monitor locating support with adjustable, mortar fill the cavity from bottom to top, and the inside gas of cavity is extruded through the exhaust subassembly, and after concrete filling was accomplished, the inside reverse hot-blast that lets in of exhaust subassembly, hot-blast promotion upper concrete solidification, and the concrete that lets in the cavity again, concrete mortar spouts in ground from the anchor subassembly, has solved the GNSS displacement monitor because geology and meteorological factor take place the skew and lead to the monitoring error.

Description

GNSS displacement monitor locating support with adjustable

Technical Field

The invention relates to the technical field of monitor positioning brackets, in particular to an adjustable GNSS displacement monitor positioning bracket.

Background

Global Navigation Satellite Systems (GNSS), also known as Global satellite navigation systems, are space-based radio navigation positioning systems that provide users with all-weather 3-dimensional coordinates and velocity and time information at any location on the surface of the earth or near earth space, including one or more satellite constellations and augmentation systems required to support a particular job. The GNSS displacement monitoring station is also called as GNSS monitoring station, GNSS displacement monitor, divide into reference station and measuring station, have the precision height, low power consumption, sexual valence relative altitude, install characteristics such as portable, this equipment accessible 4G or ethernet mode are uploaded data to environmental monitoring platform, adopt solar energy power supply's mode, and the installation does not receive the restriction of regional topography, GNSS displacement monitoring station mainly comprises GNSS antenna, solar cell panel, master control machine case (there is master control transmission module) and installing support, including reference station and measuring station two parts, this equipment accessible 4G signal network is data uploading to environmental monitoring platform, be applicable to the deformation monitoring of earth's surface displacement monitoring and building, such as landslide, side slope displacement, bridge deformation, reservoir dam and mine geological disaster etc.. In recent years, the mining of coal mines causes a large amount of surface subsidence and subsidence, which causes serious damage to artificial facilities such as buildings, roads and the like, large-area farmland damage and even loss of life and property, so that the research of the mining subsidence monitoring technology of coal mines has important theoretical and practical significance.

The existing GNSS displacement monitor positioning bracket has the problems that due to structural design defects, the GNSS displacement monitor is offset due to geological and meteorological factors to cause monitoring errors, and monitoring equipment is easy to damage when being in an environment with large sand wind for a long time.

Disclosure of Invention

The invention provides an adjustable positioning bracket for a GNSS displacement monitor, which solves the problems in the background art.

In order to achieve the above purpose, the invention is realized by the following technical scheme: an adjustable GNSS displacement monitor positioning bracket comprises a fixed plate, wherein the surface of the fixed plate is connected with a limit bolt through threads; further comprises:

the stabilizing mechanism is arranged below the fixed plate, the bottom of the fixed plate is in close contact with the ground, and the stabilizing mechanism is buried below the ground and is used for improving the connection stability with the ground; the device comprises a bottom shell fixedly connected with the lower position of the surface of a mechanism wall, an anchor assembly is connected with the inner side surface of the bottom shell through threads, an exhaust assembly is fixedly connected with the top of the bottom shell, a cavity is arranged between the mechanism wall and the bottom shell, concrete mortar is introduced into the cavity through an extension pipe, the exhaust assembly discharges gas, and after the concrete is completely filled, hot air is introduced into the bottom shell through the exhaust assembly to promote the solidification of upper concrete, and concrete is continuously injected into the bottom shell to enable the concrete to be sprayed into the ground from the anchor assembly;

the device comprises a sand prevention mechanism, wherein a monitor is fixedly connected to the top end of the sand prevention mechanism, a motor is fixedly connected to the surface of the mechanism wall, the middle position of the surface of the sand prevention mechanism is fixedly connected with a rotating shaft at the output end of the motor, and the motor drives the sand prevention mechanism to rotate on the inner side surface of the mechanism wall.

Preferably, the medial surface fixedly connected with extension pipe of drain pan, the bottom fixedly connected with grout pipe of extension pipe, the top of extension pipe extends to the top position of fixed plate, and the monitor monitors the geological deformation of surrounding environment for a long time, and long-time monitoring in-process, geological and meteorological factor cause the monitor skew to topple over even easily, and the position between mechanism wall and the drain pan sets up the cavity, and the extension pipe lets in concrete mortar in this cavity.

Preferably, the anchoring assembly comprises a connecting cylinder, the surface of the connecting cylinder is provided with threads, the surface of the connecting cylinder is connected with the inner side surface of the bottom shell through the threads, and a shrinkage opening is arranged at the lower position of the connecting cylinder.

Preferably, the medial surface fixedly connected with plastic film of connecting cylinder, the fixed surface of plastic film is connected with the stock, the top position fixedly connected with trompil ball on stock surface, the bottom of extension pipe extends to the bottom of mechanism wall, and the grout pipe is from the below position filling concrete mortar of cavity.

Preferably, the exhaust assembly comprises an inner insert, the inner insert is arranged at a position between the mechanism wall and the inner side surface of the bottom shell, and the surface of the inner insert is provided with air holes.

Preferably, the top fixedly connected with air duct of drain pan, the top fixedly connected with communicating pipe of air duct, the bottom of air duct extends to the medial surface of drain pan, and mechanism wall buries in the below position on ground, carries out spacingly through stop bolt between fixed plate and the ground, and when the sand wind is great, the cylinder is driven by protection component and slides downwards, and photovoltaic module is folded by the shrink.

Preferably, the sand prevention mechanism comprises a rotating shell, the middle position of the surface of the rotating shell is fixedly connected with a rotating shaft of the output end of the motor, and the bottom of the inner side surface of the rotating shell is fixedly connected with an electric cylinder.

Preferably, the top fixedly connected with protection component of shell medial surface rotates, protection component's medial surface fixedly connected with jar that slides, the output fixedly connected with lifter of electronic jar, the surface fixedly connected with photovoltaic module of lifter.

Preferably, the protection component comprises a limiting cylinder, the top of the limiting cylinder is fixedly connected with the top of the inner side surface of the rotating shell, the inner surface of the limiting cylinder is fixedly connected with an outer rubber sheet, the limiting cylinder is a cylindrical shell made of stainless steel metal materials, and when the lifting rod is in an extension state, the inner rubber sheet and the outer rubber sheet are positioned above the inner side surface of the limiting cylinder.

Preferably, the inner surface of the outer rubber sheet is fixedly connected with an inner rubber sheet, the top of the inner rubber sheet is fixedly connected with the lower position of the surface of the sliding cylinder, an electric turntable is sleeved on the surface of the lifting rod, the output end of the electric turntable is fixedly connected with a threaded cylinder, the surface of the threaded cylinder is connected with the inner side surface of the sliding cylinder through threads, and the electric turntable is externally connected with a driving motor to drive the threaded cylinder to rotate.

Preferably, the photovoltaic module comprises a connecting rod, the bottom of connecting rod rotates with the upper position on smooth jar surface and is connected, the fixed surface of lifter is connected with the braced frame, and the pressure of concrete makes the plastic membrane by the extrusion fracture, and the trompil ball imbeds to the throat position of connecting cylinder medial surface, and the impact of concrete makes the inside that the stock firmly inserted soil, and the trompil ball makes the inside that the concrete was poured into soil fast, and photovoltaic board below position is in the extension state.

Preferably, the surface of the supporting frame is rotationally connected with a photovoltaic plate, the surface of the photovoltaic plate is fixedly connected with an elastic shell, and the surface of the photovoltaic plate is rotationally connected with the top end of the connecting rod.

The invention provides an adjustable GNSS displacement monitor positioning bracket. The beneficial effects are as follows:

1. this GNSS displacement monitor locating support with adjustable, mortar fill the cavity from bottom to top, and the inside gas of cavity is extruded through the exhaust subassembly, and after concrete filling was accomplished, the inside reverse hot-blast that lets in of exhaust subassembly, hot-blast promotion upper concrete solidification, and the concrete that lets in the cavity again, concrete mortar spouts in ground from the anchor subassembly, has solved the GNSS displacement monitor because geology and meteorological factor take place the skew and lead to the monitoring error.

2. This GNSS displacement monitor locating support with adjustable, when the mortar is not filled up, the gas is upwards discharged through the gas pocket of interior inserted sheet, prevents that the inside atmospheric pressure of cavity from causing the plastic membrane to be fracturing in advance, when the mortar is filled completely, the inside of communicating pipe air duct lets in hot-blast, and hot-blast promotion upper concrete solidifies, then, continues to let in the concrete to the inside of cavity, the inside of the crowded plastic film of breaking of concrete and spouting into soil, the inside of the quick immersion to soil of mortar, after the concrete solidifies for the mechanism wall is more firm with the connection on ground.

3. This GNSS displacement monitor locating support with adjustable, electronic jar drive lifter downwardly moving, and photovoltaic module buries in the medial surface of rotating the shell, and the motor drives and rotates the shell and rotate, rotates the surface of shell and the medial surface rotation of mechanism wall and be connected, rotates the rotation of shell and makes the inside that the sand wind is difficult for filling to rotating the shell, rotates the shell and protects photovoltaic module and monitor, has solved monitoring facilities and is in the problem that the sand wind is great in the environment for a long time easy damage.

4. This GNSS displacement monitor locating support with adjustable, the monitor is in the monitoring state, and the carriage supports spacingly to the top position of photovoltaic board, and electronic revolving stage rotates through driving the screw thread section of thick bamboo, and the screw thread section of thick bamboo drives the slide cylinder and reciprocates, and the elastic shell between the photovoltaic board forms umbrella-shaped structure, and the sheet rubber stromatolite is protruding upwards to prevent external impurity entering the inside of rotating the shell, umbrella-shaped structure between photovoltaic board and the elastic shell protects screw thread meshing position, thereby makes the effective improvement of the anti-environmental interference ability of equipment.

5. This GNSS displacement monitor locating support with adjustable, the bottom of photovoltaic board outwards expands for photovoltaic board furthest absorbs the illumination, because the monitoring period of monitor is very long, when the sand wind comes temporarily, and the bottom of photovoltaic board is in shrinkage state, and the lifter moves down, outer sheet rubber and inlayer sheet rubber undercut, and the monitor is temporarily accomodate to the inside of rotating the shell, makes to be connected more firm between mechanism wall and the ground after the concrete solidifies, and the photovoltaic board is difficult for the skew, makes the photovoltaic efficiency of photovoltaic board higher.

Drawings

FIG. 1 is a perspective view of the entire top of an adjustable GNSS displacement monitor positioning bracket of the present invention;

FIG. 2 is a perspective view of the entire bottom of an adjustable GNSS displacement monitor positioning bracket according to the present invention;

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

FIG. 4 is a schematic view of the structure of the anchor assembly of the present invention;

FIG. 5 is a schematic view of an exhaust assembly according to the present invention;

FIG. 6 is a schematic view of the sand prevention mechanism of the present invention;

FIG. 7 is a schematic view of a protective assembly according to the present invention;

fig. 8 is a schematic structural view of the photovoltaic module of the present invention.

In the figure: 1. a fixing plate; 2. a limit bolt; 3. a stabilizing mechanism; 31. a mechanism wall; 32. a bottom case; 33. an extension tube; 34. grouting pipes; 35. an anchor assembly; 351. a connecting cylinder; 352. a plastic film; 353. a perforated ball; 354. a bolt; 36. an exhaust assembly; 361. an inner insert; 362. air holes; 363. an air duct; 364. a communicating pipe; 4. a motor; 5. a sand prevention mechanism; 51. rotating the shell; 52. an electric cylinder; 53. a protective assembly; 531. a limiting cylinder; 532. an outer layer rubber sheet; 533. an inner layer rubber sheet; 534. an electric turntable; 54. a lifting rod; 55. a slide cylinder; 56. a photovoltaic module; 561. a connecting rod; 562. a support frame; 563. a photovoltaic panel; 564. an elastic shell; 6. and a monitor.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

First embodiment: as shown in fig. 1-3, the present invention provides a technical solution: an adjustable GNSS displacement monitor positioning bracket comprises a fixed plate 1, wherein the surface of the fixed plate 1 is connected with a limit bolt 2 through threads; further comprises:

the stabilizing mechanism 3 is arranged below the fixed plate 1, the bottom of the fixed plate 1 is in close contact with the ground, and the stabilizing mechanism 3 is buried below the ground and is used for improving the connection stability with the ground; the concrete pouring device comprises a mechanism wall 31, wherein a bottom shell 32 is fixedly connected to the lower position of the surface of the mechanism wall 31, an anchor assembly 35 is connected to the inner side surface of the bottom shell 32 through threads, an exhaust assembly 36 is fixedly connected to the top of the bottom shell 32, a cavity is formed between the mechanism wall 31 and the bottom shell 32, concrete mortar is introduced into the cavity through an extension pipe 33, the exhaust assembly 36 discharges gas, after the concrete is completely filled, hot air is introduced into the bottom shell 32 through the exhaust assembly 36 to promote the solidification of upper concrete, and concrete is continuously poured into the bottom shell through the anchor assembly 35 so that the concrete is sprayed into the ground;

an extension pipe 33 is fixedly connected to the inner side surface of the bottom shell 32, a grouting pipe 34 is fixedly connected to the bottom end of the extension pipe 33, and the top end of the extension pipe 33 extends to the upper position of the fixing plate 1;

the sand prevention mechanism 5, the top fixedly connected with monitor 6 of sand prevention mechanism 5, the fixed surface of mechanism wall 31 is connected with motor 4, the middle part position of sand prevention mechanism 5 surface and the pivot fixed connection of motor 4 output, motor 4 drive sand prevention mechanism 5 at the medial surface rotation of mechanism wall 31.

During the use, monitor 6 carries out long-time monitoring to the geological deformation of surrounding environment, long-time monitoring in-process, geological and meteorological factor cause monitor 6 skew easily and topple over even, the position between mechanism wall 31 and the drain pan 32 sets up the cavity, extend pipe 33 lets in concrete mortar in this cavity, the cavity is filled from bottom to top to the mortar, the inside gas of cavity is extruded through exhaust assembly 36, after concrete fills completely, the inside reverse hot-blast that lets in of exhaust assembly 36, hot-blast promotion upper concrete solidifies, continue to let in concrete into the cavity again, concrete mortar spouts in the ground from anchor assembly 35, GNSS displacement monitor has been solved because geological and meteorological factor take place the skew and has led to the monitoring error.

Second embodiment: as shown in fig. 3, 4 and 5, the anchoring assembly 35 comprises a connecting cylinder 351, the surface of the connecting cylinder 351 is provided with threads, the surface of the connecting cylinder 351 is connected with the inner side surface of the bottom shell 32 through threads, a necking is arranged at the lower position of the connecting cylinder 351, a plastic film 352 is fixedly connected with the inner side surface of the connecting cylinder 351, an anchor rod 354 is fixedly connected with the surface of the plastic film 352, an open-pore ball 353 is fixedly connected with the upper position of the surface of the anchor rod 354, the exhaust assembly 36 comprises an embedded piece 361, the embedded piece 361 is arranged at a position between the mechanism wall 31 and the inner side surface of the bottom shell 32, an air hole 362 is formed in the surface of the embedded piece 361, an air duct 363 is fixedly connected with the top of the bottom shell 32, a communicating pipe 364 is fixedly connected with the top end of the air duct 363, and the bottom end of the air duct 363 extends to the inner side surface of the bottom shell 32.

When the device is used, the bottom end of the extension pipe 33 extends to the bottom of the mechanism wall 31, the grouting pipe 34 is filled with concrete mortar from the lower position of the cavity, when the mortar is not filled, air is discharged upwards through the air holes 362 of the embedded piece 361, the plastic film 352 is prevented from being cracked in advance due to overlarge air pressure in the cavity, when the mortar is filled completely, the communicating pipe 364 is filled with hot air into the air pipe 363, the hot air promotes the solidification of upper concrete, then, concrete is continuously filled into the cavity, the plastic film 352 is extruded by the concrete and sprayed into the soil, the mortar is quickly soaked into the soil, the device can fully fill the cavity after the upper concrete is solidified, when the concrete is sprayed out, compared with the concrete is slowly and continuously poured into the soil, the concrete sprayed out in a short time can be soaked into the deeper position of the soil, and the connection between the mechanism wall 31 and the ground is more stable after the concrete is solidified.

Third embodiment: as shown in fig. 3 and 6, a bottom shell 32 is fixedly connected to the lower position of the surface of the mechanism wall 31, an anchor assembly 35 is connected to the inner side surface of the bottom shell 32 through threads, an exhaust assembly 36 is fixedly connected to the top of the bottom shell 32, concrete is poured into the bottom of the inner side surface of the bottom shell 32, the exhaust assembly 36 discharges air, after the concrete is completely filled, hot air is introduced into the bottom shell 32 by the exhaust assembly 36 to promote the solidification of upper concrete, and concrete is continuously poured into the bottom shell through the anchor assembly 35 so that the concrete is sprayed into the ground;

the medial surface fixedly connected with extension pipe 33 of drain pan 32, the bottom fixedly connected with grout pipe 34 of extension pipe 33, the top of extension pipe 33 extends to the top position of fixed plate 1, prevent wind husky mechanism 5 is including rotating shell 51, the middle part position on shell 51 surface and the pivot fixed connection of motor 4 output rotate shell 51 medial surface, the bottom fixedly connected with electric jar 52 of shell 51 medial surface rotates, the top fixedly connected with protection subassembly 53 of shell 51 medial surface rotates, the medial surface fixedly connected with slide cylinder 55 of protection subassembly 53, the output fixedly connected with lifter 54 of electric jar 52, the surface fixedly connected with photovoltaic module 56 of lifter 54.

When the wind sand monitoring device is used, the mechanism wall 31 is buried at the lower position of the ground, the fixing plate 1 and the ground are limited through the limiting bolts 2, when wind sand is large, the sliding cylinder 55 is driven to slide downwards by the protection component 53, the photovoltaic component 56 is contracted and folded, the electric cylinder 52 drives the lifting rod 54 to move downwards, the photovoltaic component 56 is buried at the inner side surface of the rotating shell 51, the motor 4 drives the rotating shell 51 to rotate, the surface of the rotating shell 51 is rotationally connected with the inner side surface of the mechanism wall 31, wind sand is not easy to pour into the rotating shell 51 due to the rotation of the rotating shell 51, the rotating shell 51 protects the photovoltaic component 56 and the monitor 6, and the problem that monitoring device is easy to damage in a large wind sand environment for a long time is solved.

Fourth embodiment: as shown in fig. 6, 7 and 8, the protection component 53 includes a limiting cylinder 531, the top of the limiting cylinder 531 is fixedly connected with the top of the inner side surface of the rotary shell 51, the inner surface of the limiting cylinder 531 is fixedly connected with an outer rubber sheet 532, the inner surface of the outer rubber sheet 532 is fixedly connected with an inner rubber sheet 533, the top of the inner rubber sheet 533 is fixedly connected with the lower position of the surface of the sliding cylinder 55, the surface of the lifting rod 54 is fixedly connected with an electric turntable 534, the surface of the lifting rod 54 is sleeved with an electric turntable 534, the principle of the electric turntable 534 is that a worm is meshed with a worm wheel, the worm wheel is driven to rotate, the output end of the electric turntable 534 is fixedly connected with a threaded cylinder, the electric turntable 534 is externally connected with a driving motor to drive the threaded cylinder to rotate, the bottom of the threaded cylinder is fixedly connected with the top of the worm wheel, the surface of the threaded cylinder is connected with the inner side surface of the sliding cylinder 55 through threads, the rotation of the threaded cylinder drives the sliding cylinder 55 to move up and down, the electric turntable 534 and the electric cylinder 52 are controlled by a terminal, the photovoltaic component 56 includes a connecting rod 561, the bottom of the connecting rod 561 is rotationally connected with the upper position of the surface of the sliding cylinder 55, the surface of the lifting rod 54 is fixedly connected with a supporting frame, the surface of the photovoltaic plate 563 is fixedly connected with the photovoltaic plate 563, and the surface of the photovoltaic plate 562 is connected with the surface of the photovoltaic plate 563, and the photovoltaic plate 563 is fixedly connected with the surface of the photovoltaic plate 562.

When the lifting rod 54 is in an extension state, the inner rubber sheet 533 and the outer rubber sheet 532 are positioned at the upper position of the inner side surface of the limiting cylinder 531, the monitor 6 is in a monitoring state, the supporting frame 562 supports and limits the upper position of the photovoltaic plates 563, the electric turntable 534 drives the sliding cylinder 55 to move upwards through driving the threaded cylinders to rotate, the elastic shell 564 between the photovoltaic plates 563 forms an umbrella-shaped structure, the rubber sheet lamination is upwards protruded, so that external impurities are prevented from entering the rotating shell 51, and the umbrella-shaped structure between the photovoltaic plates 563 and the elastic shell 564 protects thread engagement parts, so that the environment interference resistance of equipment is effectively improved.

Fifth embodiment: as shown in fig. 4 and 8, the surface of the connecting cylinder 351 is provided with threads, the surface of the connecting cylinder 351 is connected with the inner side surface of the bottom shell 32 through threads, a necking is arranged at the lower position of the connecting cylinder 351, the inner side surface of the connecting cylinder 351 is fixedly connected with a plastic film 352, the surface of the plastic film 352 is fixedly connected with an anchor rod 354, the upper position of the surface of the anchor rod 354 is fixedly connected with an open-pore ball 353, the bottom end of the connecting rod 561 is rotationally connected with the upper position of the surface of the sliding cylinder 55, the surface of the lifting rod 54 is fixedly connected with a supporting frame 562, the surface of the supporting frame 562 is rotationally connected with a photovoltaic plate 563, the surface of the photovoltaic plate 563 is fixedly connected with an elastic shell 564, and the surface of the photovoltaic plate 563 is rotationally connected with the top end of the connecting rod 561.

When the device is used, the plastic film 352 is extruded and broken by the pressure of concrete, the perforated ball 353 is embedded into the necking position of the inner side surface of the connecting cylinder 351, the anchor rod 354 is firmly inserted into the soil by the impact of the concrete, the concrete is quickly poured into the soil by the perforated ball 353, the lower position of the photovoltaic plate 563 is in an expanded state, the bottom end of the photovoltaic plate 563 is outwards unfolded, the photovoltaic plate 563 absorbs illumination to the maximum extent, the bottom of the photovoltaic plate 563 is in a contracted state due to the very long monitoring period of the monitor 6, when the sand is blown by wind, the lifting rod 54 moves downwards, the outer rubber sheet 532 and the inner rubber sheet 533 are downwards sunken, the monitor 6 is temporarily stored into the rotating shell 51, the mechanism wall 31 is firmly connected with the ground after the concrete is solidified, the photovoltaic plate 563 is not easy to deflect, and the photovoltaic efficiency of the photovoltaic plate 563 is higher.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation. The statement "comprising an element defined by … … does not exclude the presence of other identical elements in a process, method, article or apparatus that comprises the element.

Claims (5)

1. An adjustable GNSS displacement monitor positioning bracket comprises a fixed plate (1), wherein the surface of the fixed plate (1) is connected with a limit bolt (2) through threads; characterized by further comprising:

the stabilizing mechanism (3) is arranged at the lower position of the fixed plate (1), the bottom of the fixed plate (1) is in close contact with the ground, and the stabilizing mechanism (3) is buried at the lower position of the ground and is used for improving the connection stability with the ground; the concrete grouting device comprises a mechanism wall (31), wherein a bottom shell (32) is fixedly connected to the lower position of the surface of the mechanism wall (31), an extension pipe (33) is fixedly connected to the inner side surface of the bottom shell (32), a grouting pipe (34) is fixedly connected to the bottom end of the extension pipe (33), the top end of the extension pipe (33) extends to the upper position of a fixed plate (1), an anchor assembly (35) is connected to the inner side surface of the bottom shell (32) through threads, an exhaust assembly (36) is fixedly connected to the top of the bottom shell (32), a cavity is formed between the mechanism wall (31) and the bottom shell (32), concrete mortar is introduced into the cavity through the extension pipe (33), the exhaust assembly (36) discharges air, and after concrete is completely filled, hot air is introduced into the bottom shell (32) to promote upper concrete to solidify, and concrete is continuously injected into the ground from the anchor assembly (35);

the device comprises a sand prevention mechanism (5), wherein a monitor (6) is fixedly connected to the top end of the sand prevention mechanism (5), a motor (4) is fixedly connected to the surface of a mechanism wall (31), the middle position of the surface of the sand prevention mechanism (5) is fixedly connected with a rotating shaft at the output end of the motor (4), and the motor (4) drives the sand prevention mechanism (5) to rotate on the inner side surface of the mechanism wall (31);

the wind and sand prevention mechanism (5) comprises a rotating shell (51), the middle position of the surface of the rotating shell (51) is fixedly connected with a rotating shaft at the output end of the motor (4), and the bottom of the inner side surface of the rotating shell (51) is fixedly connected with an electric cylinder (52);

the top of the inner side surface of the rotating shell (51) is fixedly connected with a protection component (53), the inner side surface of the protection component (53) is fixedly connected with a sliding cylinder (55), the output end of the electric cylinder (52) is fixedly connected with a lifting rod (54), and the surface of the lifting rod (54) is fixedly connected with a photovoltaic component (56);

the protection component (53) comprises a limit cylinder (531), the top of the limit cylinder (531) is fixedly connected with the top of the inner side surface of the rotary shell (51), and the inner surface of the limit cylinder (531) is fixedly connected with an outer layer rubber sheet (532);

the inner surface of outer sheet rubber (532) fixedly connected with inlayer sheet rubber (533), the top of inlayer sheet rubber (533) and the below position fixed connection on smooth jar (55) surface, the surface cover of lifter (54) is equipped with electronic revolving stage (534), the output fixedly connected with screw thread section of thick bamboo of electronic revolving stage (534), the surface of screw thread section of thick bamboo is connected with the medial surface of smooth jar (55) through the screw thread, the external driving motor of electronic revolving stage (534) drives screw thread section of thick bamboo rotation.

2. An adjustable GNSS displacement monitor positioning bracket according to claim 1, wherein: the anchoring assembly (35) comprises a connecting cylinder (351), threads are formed in the surface of the connecting cylinder (351), the surface of the connecting cylinder (351) is connected with the inner side face of the bottom shell (32) through the threads, and a necking is formed in the lower position of the connecting cylinder (351).

3. An adjustable GNSS displacement monitor positioning bracket according to claim 2, wherein: the inner side of the connecting cylinder (351) is fixedly connected with a plastic film (352), the surface of the plastic film (352) is fixedly connected with an anchor rod (354), and an open-pore ball (353) is fixedly connected to the upper position of the surface of the anchor rod (354).

4. An adjustable GNSS displacement monitor positioning bracket according to claim 3, wherein: the exhaust assembly (36) comprises an inner insert (361), wherein the inner insert (361) is arranged at a position between the mechanism wall (31) and the inner side surface of the bottom shell (32), and air holes (362) are formed in the surface of the inner insert (361).

5. An adjustable GNSS displacement monitor positioning bracket according to claim 4, wherein: the top fixedly connected with air duct (363) of drain pan (32), the top fixedly connected with communicating pipe (364) of air duct (363), the bottom of air duct (363) extends to the medial surface of drain pan (32).