CN116608392B

CN116608392B - Multi-dimensional adjusting structure and adjusting method for laser level meter machine

Info

Publication number: CN116608392B
Application number: CN202310632812.7A
Authority: CN
Inventors: 陆志伟
Original assignee: Changzhou Liansheng Photoelectric Technology Co ltd
Current assignee: Changzhou Liansheng Photoelectric Technology Co ltd
Priority date: 2023-05-31
Filing date: 2023-05-31
Publication date: 2023-11-10
Anticipated expiration: 2043-05-31
Also published as: CN116608392A

Abstract

The application relates to the technical field of laser level machine adjusting brackets, and discloses a multidimensional adjusting structure and an adjusting method for a laser level machine, wherein the main body mechanism further comprises a laser level, the bottom of the laser level is in threaded connection with a base plate, and the bottom of the base plate is in threaded connection with a supporting seat.

Description

Multi-dimensional adjusting structure and adjusting method for laser level meter machine

Technical Field

The application relates to the technical field of laser level machine adjusting brackets, in particular to a multidimensional adjusting structure and a multidimensional adjusting method for a laser level machine.

Background

The laser level machine is used for machining metal plates and is one of positioning equipment for marking and positioning steel plates in mechanical manufacturing, wherein a common laser level mainly comprises a laser level main body, a connecting component, a multidimensional adjusting structure, a control switch, a control system, a power supply device and other mechanisms, and the specific operation flow of the laser level is as follows: during operation, a worker installs the laser level meter main body on the surface of the multidimensional adjusting structure through the connecting component, and meanwhile, the integral installation operation of the laser level meter can be completed through the horizontal adjustment operation of the multidimensional adjusting structure by manpower, and during use, the laser level meter is controlled by using the control switch, the control system and the power supply device manually to perform laser positioning operation;

the multidimensional adjusting structure mainly comprises a main body support, a sleeve joint support, a height adjusting device and other mechanisms, and the specific use flow of the multidimensional adjusting structure is as follows: when controlling, highly adjust the structure highly in order to multidimensionally adjust through the manual work controls high adjusting device, and common multidimensionally adjust its holistic height and the level alignment of structure in the in-process of using mainly controls through the manual work to lead to common multidimensionally to adjust the structure and appear following several problems in the in-process of using:

1. the multidimensional adjusting structure is horizontally adjusted, so that certain manpower is wasted, and the main reason for the problem is that: the common height adjusting device of the multidimensional adjusting structure is mainly manually adjusted, so that the multidimensional adjusting mechanism is manually adjusted, certain manpower is wasted in the process, and the phenomenon of uneven stress of each main body support of the multidimensional adjusting structure possibly occurs through manual adjustment, so that the laser level instrument has special conditions such as deviation and the like in the use process of calibration data, and the positioning is invalid;

2. the laser level is easy to damage by external force, and the main reason for the occurrence of the problems is that: the common laser level is mainly applied to outdoor operational environment, so that the situation that the laser level is toppled down due to external force can occur in the use process, and then the laser level main body is damaged to a certain extent, so that certain economic loss is caused.

Disclosure of Invention

In order to overcome the defects in the prior art, the application provides a multidimensional adjusting structure and a multidimensional adjusting method for a laser level machine, which are used for solving the problems in the background art.

The application provides the following technical scheme: the multidimensional adjusting structure for the laser level machine comprises a main body mechanism, wherein the main body mechanism further comprises a laser level, the bottom of the laser level is in threaded connection with a base plate, the bottom of the base plate is in threaded connection with a supporting seat, the inner wall of the middle part of the supporting seat is fixedly connected with a hollow column, the bottom of the main body mechanism is provided with a lifting mechanism, the outer wall of the main body mechanism is provided with a protection mechanism, and the inner wall of the main body mechanism is provided with an adjusting protection system which is applied to the main body mechanism, the lifting mechanism and the protection mechanism for adjusting protection operation;

the bottom of the hollow column is fixedly connected with a micro base, the inner wall of the micro base is sleeved with a connecting plate, one end of the connecting plate is sleeved with a clamping groove plate, and the bottom of the micro base is fixedly embedded with an angle sensor;

the adjusting and protecting system further comprises a control center, a monitoring unit, a data processing unit, an analysis unit, a decision unit, an adjusting unit and a protecting unit;

monitoring unit: an angle sensor is arranged in the sensor, and angle data L monitored by the angle sensor are collected in real time;

a data processing unit: the system comprises a monitoring unit, a data transmission module, a data receiving module and a data storage module, wherein the data receiving module receives angle data L collected by the monitoring unit in real time and transmits the angle data L to the data storage module through the data transmission module for storage management;

analysis unit: the system comprises a threshold module, a comparison module and an analysis module, wherein the threshold module simulates angle data L generated by an angle sensor when a lifting mechanism is in an adjustment completion state, integrates the simulated angle data L into a first threshold range, the threshold module simulates angle data L generated when the lifting mechanism is in an inclined falling condition, integrates the simulated angle data L into a second threshold range, the comparison module compares real-time angle data L in a data storage module with the first threshold range and the second threshold range, and when the real-time angle data L is not in the first threshold range, the analysis module sends a first instruction, and when the real-time angle data L is in the second threshold range, the analysis module sends a second instruction;

and the control center: the control center controls the monitoring unit, the data processing unit, the analysis unit, the decision unit, the adjusting unit and the protection unit;

decision unit: the method comprises the steps of receiving a first decision control adjusting unit start executing command sent by a control center, and receiving a second decision control protecting unit start executing command sent by the control center;

an adjusting unit: an electric hydraulic column is arranged in the anti-skid pad, and the height of the first support is adjusted by electrifying the electric hydraulic column;

protection unit: the electromagnetic cabin and the electromagnetic valve are arranged in the laser level meter, and the electromagnetic cabin and the electromagnetic valve are controlled by current to start electrifying operation so as to control the protection cabin group to be in a rotary inflation state, thereby protecting the laser level meter.

In a preferred embodiment, the inner wall of the hollow column is provided with a manual adjusting device, and the manual adjusting device is rotated to control the hollow column to drive the connecting plate to adjust the height.

In a preferred embodiment, the lifting mechanism further comprises a first support, one end of the first support is provided with a fixing component, the other end of the first support is sleeved with an auxiliary support, the inner wall of the bottom of the auxiliary support is sleeved with a second support, the bottom of the second support is fixedly connected with an anti-slip pad, two sides of the bottom of the first support are fixedly connected with first support columns, and the outer wall of each first support column is sleeved with a hollow support column.

In a preferred embodiment, one end fixedly connected with second spring of first pillar, the middle part fixedly connected with electric hydraulic pressure post of first support bottom, the middle part fixedly connected with hollow cylinder on second support top, the inner wall of hollow cylinder has cup jointed the buffer rod, the bottom fixedly connected with first spring of buffer rod.

In a preferred embodiment, the inner wall of the top of the buffer rod is provided with a clamping groove, and the clamping groove of the inner wall of the top of the buffer rod is the same as one end of the electric hydraulic column in size.

In a preferred implementation mode, the protection cabin group is that multiunit protection cabin seals cup joints and constitutes, and can carry out parallel movement between each group protection cabin, the both sides at protection cabin group top are equipped with two sets of torsion spring device, a set of the inner wall of torsion spring device is equipped with the pneumatic valve, another set of the inner wall of torsion spring device runs through fixedly connected with U type hose, the one end of U type hose runs through fixedly connected with spring group, the bottom of spring group runs through fixedly connected with gas-supply pipe, and the one end meshing of gas-supply pipe is connected with the solenoid valve, and the one end of solenoid valve runs through fixedly connected with compressed gas jar, the top fixedly connected with second permanent magnetism cabin of compressed gas jar, and the outer wall of second permanent magnetism cabin is equipped with the permanent magnetism pillar, carries out fixedly connected with through magnetic attraction between permanent magnetism pillar, the laser level gauge, and the bottom welding of second permanent magnetism cabin has the compressed gas jar, the side fixedly connected with first permanent magnetism cabin of protection cabin, and the inner wall of first permanent magnetism cabin is equipped with the electromagnetism cabin.

In a preferred embodiment, the inner wall of the compressed gas tank is provided with compressed inert air, the compressed inert air is conveyed to the inner wall of the protection cabin group through the electromagnetic valve, the gas pipe, the spring group and the U-shaped hose, the protection cabin group is driven to be in a stretching state, and the stretching state of the protection cabin group is in an arch shape and the length of the protection cabin group is 1.1 times of that of the laser level.

In a preferred embodiment, a magnetic attraction force is generated between the first permanent magnet cabin and the electromagnetic cabin, the magnetic force at one end of the electromagnetic cabin is controlled by adjusting a protection system, and a sealing cover is arranged at the bottom of the compressed gas tank.

The application has the technical effects and advantages that:

1. the lifting mechanism and the adjusting protection system are arranged, so that when the lifting mechanism is in an open state, the anti-skid pad of the lifting mechanism is in contact with the construction ground, when three groups of first brackets are inclined due to different placement heights, the adjusting protection system controls the electric hydraulic columns corresponding to one side of one group of first brackets to start to conduct power-on operation, and the electric hydraulic columns start to conduct corresponding telescopic operation, so that the second brackets are driven to conduct corresponding length adjustment operation, and the integral lifting mechanism is driven to be in a horizontal state, thereby achieving the effect of automatic adjustment, and reducing certain manpower waste.

2. The application is beneficial to the regulation and protection system to control the electromagnetic cabin to disconnect the power supply by being provided with the regulation and protection system, the magnetic attraction generated by the first permanent magnet cabin and the electromagnetic cabin disappears, the protection cabin group is driven by the torsion spring force of the torsion spring device to rotate for one hundred eighty degrees, in the process of the rotation operation of the protection cabin group, the electromagnetic valve is electrified to be in an open state, the compressed inert gas in the compressed gas tank is conveyed to the inside of the protection cabin group through the electromagnetic valve, the compressed gas tank, the spring group and the U-shaped hose, the protection cabin group is driven to be in a unfolding state, and the three protection cabin groups form an annular ring, so that the laser level in a falling state is protected to a certain extent, and the damage of internal components caused by the direct contact of the laser level with the ground is avoided.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present application.

Fig. 2 is an enlarged schematic view of the structure a in fig. 1.

Fig. 3 is a schematic view of a part of the structure of the lifting mechanism of the application.

FIG. 4 is a schematic cross-sectional view of the hollow cylinder of the present application.

Fig. 5 is an enlarged schematic view of the structure at B in fig. 1.

Fig. 6 is a schematic cross-sectional view of a part of the structure of the protection cabin of the present application.

Fig. 7 is a schematic cross-sectional view of the structure at B in fig. 1.

FIG. 8 is a schematic overall flow chart of the conditioning and protecting system of the present application.

The reference numerals are: 1. a main body mechanism; 101. a laser level; 102. a base plate; 103. a support base; 104. a hollow column; 105. a connecting plate; 106. a slot plate; 107. a micro base; 108. an angle sensor; 2. a lifting mechanism; 201. a first bracket; 202. an auxiliary bracket; 203. an anti-slip pad; 204. a second bracket; 205. a hollow pillar; 206. a first support column; 207. an electric hydraulic column; 208. a hollow cylinder; 209. a buffer rod; 210. a first spring; 3. a protective mechanism; 301. a protective cabin group; 302. a U-shaped hose; 303. a torsion spring device; 304. a sealing plate; 305. a spring set; 306. a first permanent magnet compartment; 307. an electromagnetic cabin; 308. an electromagnetic valve; 309. permanent magnet support posts; 310. the second permanent magnet cabin; 311. a compressed gas tank; 312. sealing cover; 4. adjusting the protection system; 401. a control center; 402. a monitoring unit; 403. a data processing unit; 404. an analysis unit; 405. a decision unit; 406. an adjusting unit; 407. and a protection unit.

Detailed Description

The embodiments of the present application will be described more fully with reference to the accompanying drawings, and the configurations of the structures described in the following embodiments are merely illustrative, and the multi-dimensional adjustment structure and adjustment method for a laser level machine according to the present application are not limited to the structures described in the following embodiments, but all other embodiments obtained by a person skilled in the art without making any creative effort are within the scope of the present application.

Referring to fig. 1 to 2, 5 and 8, the application provides a multidimensional adjusting structure for a laser level machine, which comprises a main body mechanism 1, wherein the bottom of the main body mechanism 1 is provided with a lifting mechanism 2, the outer wall of the main body mechanism 1 is provided with a protection mechanism 3, the inner wall of the main body mechanism 1 is provided with an adjusting protection system 4, and the adjusting protection system 4 is applied to the main body mechanism 1, the lifting mechanism 2 and the protection mechanism 3 for adjusting and protecting operation;

the main body mechanism 1 further comprises a laser level 101, the bottom of the laser level 101 is in threaded connection with a base plate 102, the bottom of the base plate 102 is in threaded connection with a supporting seat 103, the inner wall of the middle of the supporting seat 103 is fixedly connected with a hollow column 104, the bottom of the hollow column 104 is fixedly connected with a micro base 107, the inner wall of the micro base 107 is sleeved with a connecting plate 105, one end of the connecting plate 105 is sleeved with a clamping groove plate 106, and the bottom of the micro base 107 is fixedly embedded with an angle sensor 108.

In the embodiment of the application, a manual adjusting device is arranged on the inner wall of the hollow column 104, and the manual adjusting device is rotated to control the hollow column 104 to drive the connecting plate 105 to adjust the height.

In the embodiment of the present application, the specific workflow of the embodiment of the present application is: when the device is used, the laser level 101 is arranged on the surface of the base plate 102 in a manual rotation mode, meanwhile, the base plate 102 is fixed on the surface of the supporting seat 103 in a manual rotation mode, the lifting mechanism 2 is in a unfolding mode to fix the main body mechanism 1 in a use place, and meanwhile, the angle sensor 108 monitors the whole angle change data of the lifting mechanism 2 in real time and transmits the angle change data to the adjusting protection system 4.

Referring to fig. 1 to 4, the application provides a multidimensional adjusting structure for a laser level machine, which comprises a lifting mechanism 2, wherein the lifting mechanism 2 further comprises a first support 201, one end of the first support 201 is provided with a fixing component, the other end of the first support 201 is sleeved with an auxiliary support 202, the inner wall of the bottom of the auxiliary support 202 is sleeved with a second support 204, the bottom of the second support 204 is fixedly connected with an anti-slip pad 203, two sides of the bottom of the first support 201 are fixedly connected with first support posts 206, the outer wall of the first support posts 206 are sleeved with hollow support posts 205, one end of each first support post 206 is fixedly connected with a second spring, the middle part of the bottom end of the first support 201 is fixedly connected with an electric hydraulic column 207, the middle part of the top end of the second support 204 is fixedly connected with a hollow column 208, the inner wall of the hollow column 208 is sleeved with a buffer rod 209, and the bottom of the buffer rod 209 is fixedly connected with a first spring 210.

In the embodiment of the application, the anti-slip rubber layer is arranged at the bottom of the anti-slip pad 203, which is favorable for playing a certain anti-slip role, the clamping groove is arranged on the inner wall of the top of the buffer rod 209, and the clamping groove of the inner wall of the top of the buffer rod 209 is the same as one end of the electric hydraulic column 207 in size, which is favorable for clamping the electric hydraulic column 207 into the hollow column 208.

In the embodiment of the present application, the specific workflow of the embodiment of the present application is: when the lifting mechanism 2 is in an open state, the anti-skid pad 203 of the lifting mechanism contacts the construction ground, when three groups of first supports 201 are inclined due to different placement heights, the adjusting and protecting system 4 controls the electric hydraulic columns 207 corresponding to one side of one group of first supports 201 to start to conduct power-on operation, and the electric hydraulic columns 207 start to conduct corresponding telescopic operation, so that the second support 204 is driven to conduct corresponding length adjustment operation, the integral lifting mechanism 2 is driven to be in a horizontal state, the automatic adjusting effect is achieved, and certain manpower waste is reduced.

Referring to fig. 5 to 7, the application provides a multidimensional adjusting structure for a laser level machine, comprising a protection mechanism 3, a protection cabin group 301 is formed by sealing and sleeving a plurality of groups of protection cabins, parallel movement can be carried out among the groups of protection cabins, two groups of torsion spring devices 303 are arranged on two sides of the top of the protection cabin group 301, an air valve is arranged on the inner wall of one group of torsion spring devices 303, a U-shaped hose 302 is fixedly connected with the inner wall of the other group of torsion spring devices 303 in a penetrating manner, a spring group 305 is fixedly connected with one end of the U-shaped hose 302 in a penetrating manner, a gas pipe is fixedly connected with the bottom of the spring group 305 in a penetrating manner, one end of the gas pipe is connected with an electromagnetic valve 308 in a meshed manner, one end of the electromagnetic valve 308 is fixedly connected with a compressed gas tank 311 in a penetrating manner, a second permanent magnet cabin 310 is fixedly connected with the top of the compressed gas tank 311, a permanent magnet strut 309 is arranged on the outer wall of the second permanent magnet cabin 310, and permanent magnet pillar 309, laser level 101 go on fixed connection through the magnetic attraction, and the bottom welding of second permanent magnet cabin 310 has compressed gas jar 311, compressed gas jar 311's inner wall is equipped with compressed inert air, compressed inert air is carried to the protection cabin group 301 inner wall through solenoid valve 308, the gas-supply pipe, spring group 305 and U type hose 302, drive protection cabin group 301 is in tensile state, tensile state protection cabin group 301 is in bow-shaped and length is 1.1 times of laser level 101, the side fixedly connected with of protection cabin group 301 first permanent magnet cabin 306, and the inner wall of first permanent magnet cabin 306 is equipped with electromagnetic cabin 307, and can produce the magnetic attraction between first permanent magnet cabin 306 and the electromagnetic cabin 307, and electromagnetic cabin 307 one end magnetic force size is controlled through adjusting protection system 4, the bottom of compressed gas jar 311 is equipped with sealed lid 312.

In the embodiment of the present application, the rubber pad is disposed on the surface of the sealing cover 312, which is beneficial to a bearing function of the compressed gas tank 311.

In the embodiment of the present application, the specific workflow of the embodiment of the present application is: the protection system 4 is adjusted to control the electromagnetic cabin 307 to disconnect the power supply, the magnetic attraction force generated by the first permanent magnet cabin 306 and the electromagnetic cabin 307 disappears, the protection cabin group 301 rotates by one hundred eighty degrees under the driving of the torsion spring force of the torsion spring device 303, in the process of rotating the protection cabin group 301, the electromagnetic valve 308 is electrified to be in an open state, compressed inert gas in the compressed gas tank 311 is conveyed to the protection cabin group 301 through the electromagnetic valve 308, the compressed gas tank 311, the spring group 305 and the U-shaped hose 302, the protection cabin group 301 is driven to be in a unfolding state, and the three protection cabin groups 301 form an annular ring, so that a certain protection effect is achieved on the laser level 101 in a falling state, and the damage of internal components caused by the direct contact of the laser level 101 to the ground is avoided.

Referring to fig. 8, the application provides a multidimensional adjusting structure for a laser level machine, which comprises an adjusting protection system 4, wherein the adjusting protection system 4 further comprises a control center 401, a monitoring unit 402, a data processing unit 403, an analyzing unit 404, a decision unit 405, an adjusting unit 406 and a protection unit 407;

monitoring unit 402: an angle sensor 108 is arranged in the sensor, and angle data L monitored by the angle sensor 108 are collected in real time;

a data processing unit 403: the system also comprises a data transmission module, a data receiving module and a data storage module, wherein the data receiving module receives the angle data L collected by the monitoring unit 402 in real time and transmits the angle data L to the data storage module for storage management through the data transmission module;

analysis unit 404: threshold module, contrast module and analysis module, threshold module simulate elevating system 2 in angle sensor 108 produced angle data L under the completion state of adjusting ₁ Angle data L to be simulated ₁ Integrating the first threshold range, and simulating angle data L generated when the lifting mechanism 2 is in a tilting and falling situation by the threshold module ₂ Angle data L to be simulated ₂ Integrating the real-time angle data L in the data storage module into a second threshold range, comparing the real-time angle data L with the first threshold range and the second threshold range by the comparison module, sending a first instruction through the analysis module when the real-time angle data L is not in the first threshold range, and sending a second instruction through the analysis module when the real-time angle data L is in the second threshold range;

control center 401: receiving a first instruction sent by the analysis unit 404 and sending a first decision to the decision unit 405, receiving a second instruction sent by the analysis unit 404 and sending a second decision to the decision unit 405, and controlling the monitoring unit 402, the data processing unit 403, the analysis unit 404, the decision unit 405, the adjusting unit 406 and the protection unit 407 by the control center 401;

decision unit 405: the first decision control adjusting unit 406 sent by the control center 401 is received to start executing the command, and the second decision control protecting unit 407 sent by the control center 401 is received to start executing the command;

an adjusting unit 406: an electric hydraulic column 207 is arranged inside, and the heights of the corresponding anti-skid pad 203 and the first bracket 201 are adjusted through the electrifying operation of the electric hydraulic column 207;

protection unit 407: the electromagnetic cabin 307 and the electromagnetic valve 308 are arranged in the protective cabin, and the electromagnetic cabin 307 and the electromagnetic valve 308 are controlled by current to start electrifying operation so as to control the protective cabin group 301 to be in a rotary inflation state, thereby protecting the laser level 101.

The specific working flow of the application is as follows:

in use, the laser level 101 is installed on the surface of the base plate 102 in a manual rotation mode, meanwhile, the base plate 102 is fixed on the surface of the supporting seat 103 in a manual rotation mode, the lifting mechanism 2 is in an unfolding mode to fix the main body mechanism 1 on a use place, and meanwhile, the angle sensor 108 monitors the whole angle change data of the lifting mechanism 2 in real time and transmits the angle change data to the adjusting protection system 4;

step two, when the lifting mechanism 2 is in an open state, the anti-skid pad 203 of the lifting mechanism contacts the construction ground, when three groups of first supports 201 are inclined due to different placement heights, the adjusting and protecting system 4 controls the electric hydraulic columns 207 corresponding to one side of one group of first supports 201 to start to conduct power-on operation, the electric hydraulic columns 207 start to conduct power-on operation, and corresponding telescopic operation is carried out, so that the second support 204 is driven to conduct corresponding length adjustment operation, and the integral lifting mechanism 2 is driven to be in a horizontal state, thereby achieving the effect of automatic adjustment and reducing certain manpower waste;

step three, when the adjusting protection system 4 monitors that the laser level 101 is in an inclined falling state, the adjusting protection system 4 controls the electromagnetic cabin 307 to disconnect the power supply, the magnetic attraction force generated by the first permanent magnetic cabin 306 and the electromagnetic cabin 307 disappears, the protection cabin group 301 rotates by one hundred eighty degrees under the driving of the torsion spring force of the torsion spring device 303, in the process of rotating the protection cabin group 301, the electromagnetic valve 308 is electrified to be in an open state, compressed inert gas in the compressed gas tank 311 is conveyed to the inside of the protection cabin group 301 through the electromagnetic valve 308, the compressed gas tank 311, the spring group 305 and the U-shaped hose 302, the protection cabin group 301 is driven to be in a unfolding state, and the three groups of protection cabin groups 301 form an annular ring, so that a certain protection effect is achieved on the laser level 101 in the falling state, and the damage of internal components caused by the direct contact of the laser level 101 to the ground is avoided.

In the drawings of the disclosed embodiments, only the structures related to the embodiments of the present disclosure are referred to, and other structures can refer to the common design, so that the same embodiment and different embodiments of the present disclosure can be combined with each other under the condition of no conflict;

finally: the foregoing description of the preferred embodiments of the application is not intended to limit the application to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the application are intended to be included within the scope of the application.

Claims

1. The utility model provides a laser level machine multidimensional adjustment structure, includes main part mechanism (1), main part mechanism (1) still includes laser level (101), the bottom threaded connection of laser level (101) has bed plate (102), the bottom threaded connection of bed plate (102) has supporting seat (103), the inner wall fixedly connected with hollow post (104) at supporting seat (103) middle part, its characterized in that: the bottom of the main body mechanism (1) is provided with a lifting mechanism (2), the outer wall of the main body mechanism (1) is provided with a protection mechanism (3), the inner wall of the main body mechanism (1) is provided with an adjusting protection system (4), and the adjusting protection system (4) is applied to the main body mechanism (1), the lifting mechanism (2) and the protection mechanism (3) for adjusting protection operation;

the bottom of the hollow column (104) is fixedly connected with a micro base (107), the inner wall of the micro base (107) is sleeved with a connecting plate (105), one end of the connecting plate (105) is sleeved with a clamping groove plate (106), and the bottom of the micro base (107) is fixedly embedded with an angle sensor (108);

the regulating protection system (4) further comprises a control center (401), a monitoring unit (402), a data processing unit (403), an analysis unit (404), a decision unit (405), a regulating unit (406) and a protection unit (407);

monitoring unit (402): an angle sensor (108) is arranged in the sensor, and angle data L monitored by the angle sensor (108) are collected in real time;

a data processing unit (403): the system also comprises a data transmission module, a data receiving module and a data storage module, wherein the data receiving module receives the angle data L collected by the monitoring unit (402) in real time and transmits the angle data L to the data storage module for storage management through the data transmission module;

analysis unit (404): the threshold module simulates angle data L generated by the angle sensor (108) when the lifting mechanism (2) is in a regulating completion state ₁ Angle data L to be simulated ₁ Integrating the first threshold range, wherein the threshold module simulates angle data L generated when the lifting mechanism (2) is in a tilting and falling situation ₂ Angle data L to be simulated ₂ Integrating the real-time angle data L in the data storage module into a second threshold range, comparing the real-time angle data L with the first threshold range and the second threshold range by the comparison module, sending a first instruction through the analysis module when the real-time angle data L is not in the first threshold range, and sending a second instruction through the analysis module when the real-time angle data L is in the second threshold range;

control center (401): the control center (401) controls the monitoring unit (402), the data processing unit (403), the analysis unit (404), the decision unit (405), the adjusting unit (406) and the protection unit (407);

decision unit (405): the first decision control adjusting unit (406) sent by the control center (401) is received to start executing the command, and the second decision control protecting unit (407) sent by the control center (401) is received to start executing the command;

an adjustment unit (406): an electric hydraulic column (207) is arranged in the anti-skid device, and the height of the anti-skid pad (203) and the first bracket (201) are adjusted by electrifying the electric hydraulic column (207);

protection unit (407): an electromagnetic cabin (307) and an electromagnetic valve (308) are arranged in the protective cabin, and the electromagnetic cabin (307) and the electromagnetic valve (308) are controlled by current to start electrifying operation so as to control the protective cabin group (301) to be in a rotary inflation state, so that the laser level meter (101) is protected;

the protection cabin group (301) is formed by sleeving a plurality of groups of protection cabins in a sealing manner, the protection cabins of each group can move in parallel, two groups of torsion spring devices (303) are arranged on two sides of the top of the protection cabin group (301), one group of torsion spring devices (303) are provided with air valves on the inner walls of the torsion spring devices (303), the other group of torsion spring devices (303) are fixedly connected with U-shaped hoses (302) in a penetrating manner, one end of each U-shaped hose (302) is fixedly connected with a spring group (305) in a penetrating manner, the bottom of each spring group (305) is fixedly connected with an air pipe in a penetrating manner, one end of each air pipe is connected with an electromagnetic valve (308) in a meshed manner, one end of each electromagnetic valve (308) is fixedly connected with a compressed air tank (311) in a penetrating manner, the top of each compressed air tank (311) is fixedly connected with a second permanent magnet cabin (310), permanent magnet struts (309) are arranged on the outer walls of the second permanent magnet cabin (310), the permanent magnet struts (309) and the laser level meter (101) are fixedly connected with each other through magnetic attraction, compressed air tanks (311) are welded on the bottoms of the second permanent magnet cabin (310), the side of the protection cabin group (301) is fixedly connected with a first permanent magnet cabin (306), and the first permanent magnet cabin (306) is arranged on the inner wall of the first permanent magnet cabin (307);

the device comprises the following operation steps:

when the device is used, the laser level meter (101) is arranged on the surface of the base plate (102) in a manual rotation mode, meanwhile, the base plate (102) is fixed on the surface of the supporting seat (103) in a manual rotation mode, the lifting mechanism (2) is arranged in an unfolding mode to fix the main body mechanism (1) at a use place, and meanwhile, the angle sensor (108) monitors the integral angle change data of the lifting mechanism (2) in real time and transmits the integral angle change data to the adjusting protection system (4);

step two, when the lifting mechanism (2) is in an open state, the anti-skid pad (203) of the lifting mechanism contacts the construction ground, when three groups of first supports (201) incline due to different placement heights, the adjusting protection system (4) controls the electric hydraulic column (207) corresponding to one side of the group of first supports (201) to start to conduct electrifying operation, and the electric hydraulic column (207) starts to conduct electrifying operation to conduct corresponding telescopic operation, so that the second support (204) is driven to conduct corresponding length adjusting operation, and the whole lifting mechanism (2) is driven to be in a horizontal state;

step three, when the adjusting protection system (4) monitors that the laser level meter (101) is in an inclined falling state, the adjusting protection system (4) controls the electromagnetic cabin (307) to disconnect from the power supply, the magnetic attraction generated by the first permanent magnetic cabin (306) and the electromagnetic cabin (307) disappears, the protection cabin group (301) is driven by the torsion spring force of the torsion spring device (303) to rotate for one hundred eighty degrees, the electromagnetic valve (308) is electrified to be in an open state in the rotating operation process of the protection cabin group (301), compressed inert gas in the compressed gas tank (311) is conveyed to the inside of the protection cabin group (301) through the electromagnetic valve (308), the compressed gas tank (311), the spring group (305) and the U-shaped hose (302), the protection cabin group (301) is driven to be in a spreading state, and the three groups of protection cabin groups (301) form an annular ring, so that the laser level meter (101) in the falling state is protected to a certain extent.

2. The multi-dimensional adjustment structure for a laser level machine according to claim 1, wherein: the inner wall of the hollow column (104) is provided with a manual adjusting device, and the manual adjusting device is rotated to control the hollow column (104) to drive the connecting plate (105) to adjust the height.

3. The multi-dimensional adjustment structure for a laser level machine according to claim 1, wherein: elevating system (2) still includes first support (201), the one end of first support (201) is equipped with fixed subassembly, auxiliary support (202) have been cup jointed to the other end of first support (201), second support (204) have been cup jointed to the inner wall of auxiliary support (202) bottom, the bottom fixedly connected with slipmat (203) of second support (204), the both sides fixedly connected with first pillar (206) of first support (201) bottom, hollow pillar (205) have been cup jointed to the outer wall of first pillar (206).

4. A multi-dimensional adjustment structure for a laser level machine according to claim 3, wherein: one end fixedly connected with second spring of first pillar (206), the middle part fixedly connected with electric hydraulic pressure post (207) of first support (201) bottom, the middle part fixedly connected with hollow cylinder (208) on second support (204) top, buffer rod (209) have been cup jointed to the inner wall of hollow cylinder (208), the bottom fixedly connected with first spring (210) of buffer rod (209).

5. The multi-dimensional adjustment structure for a laser level machine of claim 4, wherein: the inner wall at the top of the buffer rod (209) is provided with a clamping groove, and the clamping groove at the inner wall at the top of the buffer rod (209) is identical to one end of the electric hydraulic column (207) in size.

6. The multi-dimensional adjustment structure for a laser level machine according to claim 1, wherein: the inner wall of the compressed gas tank (311) is provided with compressed inert air, the compressed inert air is conveyed to the inner wall of the protection cabin group (301) through the electromagnetic valve (308), the gas pipe, the spring group (305) and the U-shaped hose (302), the protection cabin group (301) is driven to be in a stretching state, and the stretching state protection cabin group (301) is in an arch shape and has the length which is 1.1 times that of the laser level instrument (101).

7. The multi-dimensional adjustment structure for a laser level machine of claim 6, wherein: magnetic attraction force can be generated between the first permanent magnet cabin (306) and the electromagnetic cabin (307), the magnetic force of one end of the electromagnetic cabin (307) is controlled through adjusting the protection system (4), and a sealing cover (312) is arranged at the bottom of the compressed gas tank (311).