CN113945767A - Multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device - Google Patents

Abstract

The invention provides a multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device which comprises a movable base, movable brake wheels, a protection supply box, a pushing frame, a power supply storage assembly, a liftable shielding protection display frame structure, a slidable supporting and fixing seat structure, a slidable locking storage box structure, a liftable rotating test seat structure, a connecting seat, a lifting motor assembly, a maintenance seat, a first U-shaped seat, a second U-shaped seat, a rotating supporting rod, a protecting rod and a protecting ring, wherein the movable brake wheels are respectively connected to four corners of the lower end of the movable base through bolts. The shielding cover, the display frame, the control display mechanism, the L-shaped sliding rod and the protection supply box are arranged, so that the display frame and the control display mechanism are inserted in the middle position of the upper inner part of the protection supply box in the using process, the protection work of electrical equipment is facilitated in the using process, and the test work of the electrical equipment is prevented from being affected by moisture.

Description

Multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device

Technical Field

The invention belongs to the technical field of electromagnetic field radiation testing devices, and particularly relates to a multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device.

Background

All objects in nature constantly transfer heat outwards in the form of electromagnetic waves as long as the temperature is above zero, which is called radiation. The energy emitted by an object by radiation is called radiant energy, radiation for short. Radiation has an important feature in that it is "peer-to-peer". No matter the temperature of the object (gas) is high or low, the object A radiates to the object B, and the object B radiates to the object A. The testing device is required to be used for testing in the process of carrying out overhead wiring and mounting electrical equipment at high altitude.

However, the existing testing device also has the problems that the device protection work is inconvenient to carry out in the process of carrying out the electromagnetic test, the position adjustment work is inconvenient to carry out in the test process, the device which is sent out by the high-altitude electromagnetic field is inconvenient to maintain in the using process, and the adjustment is inconvenient to carry out according to the height and the angle of the device to be tested.

Therefore, it is necessary to provide a multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device.

Disclosure of Invention

In order to solve the technical problems, the invention provides a multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device, which is used for solving the problems that the existing testing device is inconvenient to carry out equipment protection work in the process of carrying out electromagnetic testing, is inconvenient to carry out position adjustment work in the testing process, is inconvenient to maintain equipment emitted by a high-altitude electromagnetic field in the using process and is inconvenient to adjust according to the height and the angle of the equipment to be tested. A multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device comprises a movable base, movable brake wheels, a protection supply box, a pushing frame, a power supply storage assembly, a liftable shielding display frame structure, a slidable supporting and fixing seat structure, a slidable locking and storing box structure, a liftable rotating test seat structure, a connecting seat, a lifting motor assembly, a maintenance seat, a first U-shaped seat, a second U-shaped seat, a rotating supporting rod, a protecting rod and a protecting ring, wherein the movable brake wheels are respectively bolted at four corners of the lower end of the movable base; the protective supply box is connected to the middle position of the right side of the upper end of the movable base through a bolt; the pushing frame is connected to the right side of the upper end of the movable base through a bolt and is arranged on the right side of the protection supply box; the power supply storage assembly is connected to the middle position of the inner bottom end of the protection supply box through a bolt; the liftable shielding protection display frame structure is arranged in the middle of the upper inside of the protection supply box; the slidable supporting fixed seat structure is arranged on the left side of the upper end of the movable base and is arranged on the left side of the connecting seat; the slidable locking storage box structure is arranged on the outer wall of the upper end of the protection ring; the lifting and rotating test seat structure is arranged at the upper end of the sliding locking storage box structure; the connecting seat is connected to the left side of the middle position of the upper end of the movable base through a bolt; the lifting motor assembly is connected to the middle position of the upper end of the connecting seat through a bolt; the first U-shaped seats are respectively arranged at the upper ends of the slidable supporting and fixing seat structures; the second U-shaped seat is respectively bolted at the middle positions of the left side and the right side of the lower end of the maintenance seat; the lower ends of the rotating support rods are respectively connected to the middle position inside the upper side of the first U-shaped seat in a shaft mode; the upper ends of the rotating support rods are respectively connected to the middle position inside the lower side of the second U-shaped seat in a shaft mode; the lower end of the guard bar is respectively connected with the periphery of the upper end of the maintenance seat through bolts; the upper end of the guard bar is respectively bolted at the periphery of the lower end of the guard ring; the lifting shielding protection display frame structure comprises a shielding cover, a lifting rod, a display frame, a control display mechanism, an L-shaped sliding rod and a first locking nut, wherein the lifting rod is connected to the middle position of the upper end of the shielding cover through a bolt; the upper end of the display frame is connected with the middle position of the lower end of the shielding cover through a bolt; the control display mechanism is connected to the middle position of the inner bottom end of the display frame through a bolt; the upper end of the L-shaped sliding rod is respectively bolted at the middle positions of the left side and the right side of the lower end of the shielding cover; and the first locking nuts are respectively in threaded connection with the outer walls of the left side and the right side of the lower end of the L-shaped sliding rod.

Preferably, the slidable support fixing seat structure comprises an inclined L-shaped seat, a sliding groove, a first pulley, a deep groove ball bearing, a sliding block and a threaded pipe, wherein the sliding groove is formed in the right side of the upper end of the inclined L-shaped seat; the first pulley is sequentially coupled to the lower part of the inner wall of the sliding groove from left to right; the deep groove ball bearing is embedded in the middle position of the left side of the inclined L-shaped seat; the lower end of the sliding block is inserted at the bottom end of the sliding groove in a sliding manner; the threaded pipe penetrates through the middle position inside the upper end of the sliding block and is arranged in a threaded connection mode; the left end of the threaded pipe is inserted into the inner ring of the deep groove ball bearing.

Preferably, the slidable locking storage box structure comprises an inverted U-shaped sliding frame, a second pulley, a puller bolt, a tool box, a hanging plate and a hook, wherein the second pulley is sequentially axially connected to the upper part of the inner wall of the inverted U-shaped sliding frame from left to right; the puller bolt is in threaded connection with the middle position of the front surface of the inverted U-shaped sliding frame; the tool box is connected to the lower part of the rear surface of the inverted U-shaped sliding frame through bolts; the hanging plate is connected to the middle position of the lower part of the front surface of the inverted U-shaped sliding frame through a bolt; the hooks are sequentially welded in the middle of the front surface of the hanging plate from left to right.

Preferably, the lifting and rotating test seat structure comprises a test mechanism, a test seat, a lifting rod, a rotating pipe, a locking nut, a U-shaped frame and a second bolt and nut, wherein the test mechanism is connected to the middle position of the upper end of the test seat through a bolt; the upper end of the lifting rod is coupled to the middle position inside the lower end of the test seat; the lower end of the lifting rod is in threaded connection with the middle position inside the upper side of the rotating pipe; the locking nut is in threaded connection with the upper part of the outer wall of the lifting rod; the lower end of the rotating pipe is inserted in the middle of the upper inner part of the U-shaped frame; and bolts in the second bolt and nuts respectively penetrate through the middle inside the upper end of the U-shaped frame and the middle inside the lower end of the rotating pipe and are in threaded connection with the nuts.

Preferably, the power storage component is respectively connected with the control display mechanism and the testing mechanism through wires.

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

1. according to the invention, the shielding cover, the display frame, the control display mechanism, the L-shaped sliding rod and the protection supply box are arranged, so that the display frame and the control display mechanism are inserted in the middle position of the upper inner part of the protection supply box in the use process, the protection work of electrical equipment in use is facilitated, and the test work of the electrical equipment is prevented from being affected by dampness.

2. According to the invention, the arrangement of the testing mechanism, the testing seat, the lifting rod, the rotating pipe, the locking nut, the U-shaped frame and the second bolt nut is beneficial to the arrangement of the lifting rod and the rotating pipe in a threaded connection manner in the use process, so that the height of the testing mechanism is convenient to adjust, and the lower end of the rotating pipe is inserted in the middle position inside the upper side of the U-shaped frame, so that the angle of the testing mechanism is beneficial to adjusting.

3. According to the invention, the arrangement of the inverted U-shaped sliding frame, the second pulley, the tool box, the hanging plate, the hook and the protective ring is beneficial to placing tools through the tool box and the hook in the test process, and the maintenance and overhaul work of the high-altitude magnetic field equipment is facilitated in the work process.

4. According to the invention, the arrangement of the inverted U-shaped sliding frame, the second pulley, the puller bolt, the maintenance seat, the protection rod and the protection ring is beneficial to sliding at the upper end of the protection ring through the inverted U-shaped sliding frame in the use process, so that the position of the testing mechanism can be conveniently adjusted in the work process, and the testing work is convenient.

5. According to the invention, the arrangement of the shielding cover, the display frame, the control display mechanism, the L-shaped sliding rod, the first locking nut and the protective supply box is beneficial to screwing the first locking nut after the shielding cover is lifted upwards in the use process, so that the fixing work of the control display mechanism is convenient in the test process.

6. According to the invention, the arrangement of the inclined L-shaped seat, the sliding groove, the first pulley, the deep groove ball bearing, the sliding block and the threaded pipe is beneficial to supporting the sliding block through the first pulley in the use process, so that the sliding block is convenient to move and work in an auxiliary manner, meanwhile, the lifting work of the maintenance seat is facilitated, and the maintenance work of high-altitude electromagnetic field equipment in the test process is convenient.

7. According to the invention, the U-shaped frame, the inverted U-shaped sliding frame, the second pulley, the puller bolt and the protective ring are arranged in a mutually matched manner, so that the puller bolt can be screwed down in the testing process, the puller bolt and the protective ring are arranged in a contact manner, and the inverted U-shaped sliding frame can be conveniently fixed in the testing process.

8. According to the invention, the arrangement of the testing mechanism, the testing seat, the lifting rod, the rotating tube and the locking nut is beneficial to screwing the locking nut in the testing process, and the locking nut and the rotating tube are arranged in a contact manner, so that the length fixing work of the lifting rod and the rotating tube is convenient to carry out in the testing process.

9. According to the invention, the arrangement of the movable base, the movable brake wheel, the protective supply box, the pushing frame and the power supply storage component is beneficial to pushing the movable base to move in the using process, and the high-altitude electromagnetic field radiation equipment can be conveniently tested at different positions.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic structural view of the liftable shielding display frame structure of the invention.

Fig. 3 is a schematic structural view of the slidable support holder structure of the present invention.

Fig. 4 is a schematic structural view of the structure of the slide-lock storage box of the present invention.

Fig. 5 is a schematic structural diagram of the liftable rotation test seat structure of the invention.

In the figure:

1. a movable base; 2. moving the brake wheel; 3. a protective supply tank; 4. a pushing frame; 5. a power storage component; 6. a liftable shielding display frame structure; 61. a shielding cover; 62. lifting the rod; 63. a display stand; 64. controlling a display mechanism; 65. an L-shaped slide bar; 66. a first lock nut; 7. a slidable support holder structure; 71. an inclined L-shaped seat; 72. a sliding groove; 73. a first pulley; 74. a deep groove ball bearing; 75. a slider; 76. a threaded pipe; 8. a slidable locking storage box structure; 81. an inverted U-shaped sliding frame; 82. a second pulley; 83. jacking the bolt; 84. a tool box; 85. a hanging plate; 86. hooking; 9. the test seat structure can be lifted and rotated; 91. a testing mechanism; 92. a test seat; 93. a lifting rod; 94. rotating the tube; 95. locking the nut; 96. a U-shaped frame; 97. a second bolt and nut; 10. a connecting seat; 11. a lift motor assembly; 12. a maintenance seat; 13. a first U-shaped seat; 14. a second U-shaped seat; 15. rotating the supporting rod; 16. a guard bar; 17. a guard ring.

Detailed Description

The invention is described in detail with reference to the accompanying drawings, as shown in fig. 1 and fig. 2, a multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device comprises a movable base 1, a movable brake wheel 2, a protection supply box 3, a pushing frame 4, a power supply storage component 5, a liftable shielding protection display frame structure 6, a slidable supporting and fixing seat structure 7, a slidable locking storage box structure 8, a liftable rotation testing seat structure 9, a connecting seat 10, a lifting motor component 11, a maintenance seat 12, a first U-shaped seat 13, a second U-shaped seat 14, a rotation supporting rod 15, a protection rod 16 and a protection ring 17, wherein the movable brake wheel 2 is respectively bolted at four corners of the lower end of the movable base 1; the protective supply box 3 is connected to the middle position of the right side of the upper end of the movable base 1 through a bolt; the pushing frame 4 is connected to the right side of the upper end of the movable base 1 through bolts and is arranged on the right side of the protective supply box 3; the power storage component 5 is connected to the middle position of the inner bottom end of the protection supply box 3 through a bolt; the liftable shielding display frame structure 6 is arranged in the middle of the upper inside of the shielding supply box 3; the slidable supporting fixed seat structure 7 is installed on the left side of the upper end of the movable base 1 and is arranged on the left side of the connecting seat 10; the slidable locking storage box structure 8 is arranged on the outer wall of the upper end of the protection ring 17; the lifting and rotating test seat structure 9 is arranged at the upper end of the sliding locking storage box structure 8; the connecting seat 10 is connected to the left side of the middle position of the upper end of the movable base 1 through a bolt; the lifting motor assembly 11 is connected to the middle position of the upper end of the connecting seat 10 through a bolt; the first U-shaped seats 13 are respectively arranged at the upper ends of the slidable supporting and fixing seat structures 7; the second U-shaped seat 14 is respectively bolted at the middle positions of the left side and the right side of the lower end of the maintenance seat 12; the lower ends of the rotating support rods 15 are respectively connected to the middle position inside the upper side of the first U-shaped seat 13 in a shaft mode; the upper ends of the rotating support rods 15 are respectively connected to the middle position inside the lower side of the second U-shaped seat 14 in a shaft mode; the lower end of the guard bar 16 is respectively bolted at the periphery of the upper end of the maintenance seat 12; the upper end of the guard bar 16 is respectively bolted at the periphery of the lower end of the guard ring 17; the lifting shielding protection display frame structure 6 comprises a shielding cover 61, a lifting rod 62, a display frame 63, a control display mechanism 64, an L-shaped sliding rod 65 and a first locking nut 66, wherein the lifting rod 62 is in bolted connection with the middle position of the upper end of the shielding cover 61; the upper end of the display frame 63 is bolted to the middle position of the lower end of the shielding cover 61; the control display mechanism 64 is connected to the middle position of the inner bottom end of the display frame 63 through a bolt; the upper end of the L-shaped sliding rod 65 is respectively bolted at the middle positions of the left side and the right side of the lower end of the shielding cover 61; the first locking nuts 66 are respectively in threaded connection with the outer walls of the left side and the right side of the lower end of the L-shaped sliding rod 65; when carrying out the high altitude magnetic field test, promote removal base 1 and remove, will remove base 1 and remove to suitable position to will remove base 1 and fix, loosen first lock nut 66, grab and lift pole 62 and lift up, will control display mechanism 64 and remove to the upper end at protection supply box 3, carry out light through shielding lid 61 and shelter from the work, prevent that sunshine from shining control display mechanism 64 and influencing observation work, then screw up first lock nut 66, fix control display mechanism 64.

In this embodiment, referring to fig. 3, the slidable supporting and fixing seat structure 7 includes an inclined L-shaped seat 71, a sliding groove 72, a first pulley 73, a deep groove ball bearing 74, a sliding block 75, and a threaded pipe 76, where the sliding groove 72 is opened at the right side of the upper end of the inclined L-shaped seat 71; the first pulley 73 is sequentially axially connected with the lower part of the inner wall of the sliding groove 72 from left to right; the deep groove ball bearing 74 is embedded in the middle position of the left side of the inclined L-shaped seat 71; the lower end of the sliding block 75 is inserted at the bottom end of the sliding groove 72 in a sliding manner; the threaded pipe 76 penetrates through the middle position inside the upper end of the sliding block 75 and is arranged in a threaded connection mode; the left end of the threaded pipe 76 is inserted into the inner ring of the deep groove ball bearing 74; after fixing control display mechanism 64, turn on power controlgear, make elevator motor assembly 11 begin work, in-process at elevator motor assembly 11 work drives screwed pipe 76 and rotates, set up through screwed pipe 76 and sliding block 75 threaded connection, make sliding block 75 remove to the left side, drive first U type seat 13 simultaneously and remove, in-process that first U type seat 13 removed, drive rotation branch 15 and rotate, through rotating branch 15 coupling setting, make rotation branch 15 support maintenance seat 12 and carry out the elevating work, conveniently carry out high altitude magnetic field test work at the in-process that uses.

In this embodiment, referring to fig. 4, the slidable locking storage box structure 8 includes an inverted U-shaped sliding frame 81, a second pulley 82, a tightening bolt 83, a tool box 84, a hanging plate 85 and a hook 86, wherein the second pulley 82 is sequentially pivoted on the upper portion of the inner wall of the inverted U-shaped sliding frame 81 from left to right; the puller bolt 83 is in threaded connection with the middle position of the front surface of the inverted U-shaped sliding frame 81; the tool box 84 is bolted to the lower part of the rear surface of the inverted U-shaped sliding frame 81; the hanging plate 85 is connected to the middle position of the lower part of the front surface of the inverted U-shaped sliding frame 81 through a bolt; the hooks 86 are sequentially welded in the middle of the front surface of the hanging plate 85 from left to right; at the in-process that carries out the magnetic field test, loosen the jack bolt 83, promote the type of falling U carriage 81 and remove, will fall the type of U carriage 81 and remove to the suitable position in guard ring 17 upper end, the convenience is according to the position of test at the in-process of test, carry out position control work, place the instrument that the maintenance of equipment used at toolbox 84 inside or articulate at the outer wall of couple 86 at the in-process of carrying out the test, the convenience carries out instrument at the in-process of test and carries the work, thereby accomplish the magnetic field test work.

In this embodiment, as shown in fig. 5, the liftable and rotatable test base structure 9 includes a test mechanism 91, a test base 92, a lifting rod 93, a rotatable tube 94, a lock nut 95, a U-shaped frame 96 and a second bolt and nut 97, wherein the test mechanism 91 is bolted to the middle position of the upper end of the test base 92; the upper end of the lifting rod 93 is coupled to the middle position inside the lower end of the test seat 92; the lower end of the lifting rod 93 is in threaded connection with the middle position inside the upper side of the rotating pipe 94; the locking nut 95 is in threaded connection with the upper part of the outer wall of the lifting rod 93; the lower end of the rotating pipe 94 is inserted in the middle of the upper inside of the U-shaped frame 96; bolts in the second bolt and nut 97 respectively penetrate through the middle inside the upper end of the U-shaped frame 96 and the middle inside the lower end of the rotating pipe 94 and are in threaded connection with the nuts; before the magnetic field test work is carried out, nuts in the second bolt and nut 97 are loosened, the angle of the rotating pipe 94 is rotated, the angle of the rotating pipe 94 is adjusted, the nuts in the second bolt and nut 97 are screwed, then the locking nut 95 is loosened as required, the lifting rod 93 is rotated, the lifting rod 93 and the rotating pipe 94 are arranged in a threaded connection mode through the lifting rod 93 and the rotating pipe 94, the length of the lifting rod 93 and the length of the rotating pipe 94 are adjusted, the locking nut 95 is screwed, the height and the angle of the test mechanism 91 are conveniently adjusted in the process of testing the magnetic field, detected data information is transmitted to the inside of the control display mechanism 64 through the test mechanism 91, and then the test work of the radiation sensitivity of the high-altitude electromagnetic field is completed.

In this embodiment, specifically, a stainless steel rod is inserted into the middle position of the upper end of the pushing frame 4; the connecting seat 10 is arranged at the middle position of the lower part of the left side of the protective supply box 3; the protective supply box 3 adopts a stainless steel box with slide holes arranged in the middle positions of the left side and the right side; the rotating support rods 15 are stainless steel rods and are provided with a plurality of rotating support rods; the rotating support rods 15 are arranged in a shaft connection mode.

In this embodiment, specifically, the display frame 63 is a U-shaped stainless steel frame and is disposed at the upper part between the L-shaped sliding rods 65; the lower end of the shielding cover 61 is glued with a silica gel ring.

In the present embodiment, specifically, the shielding cover 61 covers the upper end of the protective supply box 3; the left side and the right side of the lower end of the L-shaped sliding rod 65 respectively penetrate through sliding holes formed in the left and the right joint measurement of the protective supply box 3; the first locking nuts 66 are respectively arranged at the lower parts of the left side and the right side of the protective supply box 3; the display frame 63 and the control display mechanism 64 are arranged at the middle position of the upper inner part of the protective supply box 3.

In this embodiment, specifically, the lower end of the sliding block 75 is disposed in contact with the upper end of the first pulley 73; the inner ring of the deep groove ball bearing 74 is in interference fit with the outer wall of the left end of the threaded pipe 76.

In this embodiment, specifically, the inclined L-shaped seat 71 is bolted to the middle position on the left side of the upper end of the moving base 1; the right end of the threaded pipe 76 is connected with the outer wall of the output shaft of the lifting motor assembly 11 in a key mode; the first U-shaped seat 13 is respectively bolted at the middle position of the left side of the upper end of the inclined L-shaped seat 71 and the middle position of the upper end of the sliding block 75.

In this embodiment, specifically, the tightening bolt 83 is disposed at the lower end of the second pulley 82; the lower part of the inner wall of the inverted U-shaped sliding frame 81 is respectively glued with a silica gel pad; the hook 86 is a stainless steel hook.

In this embodiment, specifically, the inverted U-shaped sliding frame 81 is slidably sleeved on the left side of the outer wall of the upper end of the guard ring 17; the lower end of the second pulley 82 is contacted with the upper end of the guard ring 17; the tool box 84 is arranged on the inner wall of the guard bar 16; the hanging plate 85 is arranged on the outer wall of the guard bar 16.

In this embodiment, specifically, the lock nut 95 is disposed at the upper end of the rotating tube 94 and is in contact with the rotating tube; the rotating tube 94 is pivotally connected to the U-shaped frame 96 via a second bolt and nut 97.

In this embodiment, specifically, the U-shaped frame 96 is bolted to the middle of the upper end of the inverted U-shaped sliding frame 81 and is disposed on the left side of the upper end of the guard ring 17.

In this embodiment, specifically, the power storage module 5 is respectively connected to the control display mechanism 64 and the testing mechanism 91 through wires.

Principle of operation

In the invention, when a high-altitude magnetic field test is carried out, the movable base 1 is pushed to move, the movable base 1 is moved to a proper position, the movable base 1 is fixed, the first locking nut 66 is loosened, the lifting rod 62 is grasped to lift upwards, the control display mechanism 64 is moved to the upper end of the protective supply box 3, the light shielding work is carried out through the shielding cover 61 to prevent the sunlight from irradiating the control display mechanism 64 to influence the observation work, then the first locking nut 66 is screwed, the control display mechanism 64 is fixed, after the control display mechanism 64 is fixed, the power supply control equipment is turned on to enable the lifting motor component 11 to start working, the threaded pipe 76 is driven to rotate in the working process of the lifting motor component 11, the sliding block 75 is moved to the left side through the threaded connection of the threaded pipe 76 and the sliding block 75, and the first U-shaped seat 13 is driven to move at the same time, in the moving process of the first U-shaped seat 13, the rotating support rod 15 is driven to rotate, the rotating support rod 15 is arranged in a shaft connection mode through the rotating support rod 15, the rotating support rod 15 supports the maintenance seat 12 to perform lifting work, high-altitude magnetic field testing work is conveniently performed in the using process, in the magnetic field testing process, the puller bolt 83 is loosened, the inverted U-shaped sliding frame 81 is pushed to move, the inverted U-shaped sliding frame 81 is moved to a proper position at the upper end of the protection ring 17, position adjusting work is conveniently performed according to the testing position in the testing process, tools used by maintenance equipment are placed inside the tool box 84 or hung on the outer wall of the hook 86 in the testing process, tool carrying work is conveniently performed in the testing process, therefore, the magnetic field testing work is completed, before the magnetic field testing work is performed, nuts in the second bolt nuts 97 are loosened, the angle of the rotating pipe 94 is rotated, the angle of the rotating pipe 94 is adjusted, the nut in the second bolt and nut 97 is screwed, then the locking nut 95 is loosened according to needs, the lifting rod 93 is rotated, the lifting rod 93 and the rotating pipe 94 are in threaded connection, the lengths of the lifting rod 93 and the rotating pipe 94 are adjusted, the locking nut 95 is screwed, the height and the angle of the testing mechanism 91 are conveniently adjusted in the process of testing the magnetic field, detected data information is transmitted to the inside of the control display mechanism 64 through the testing mechanism 91, and then the testing work of the radiation sensitivity of the high-altitude electromagnetic field is completed.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention.

Claims (8)

1. A multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device comprises a movable base (1), movable brake wheels (2), a protection supply box (3), a pushing frame (4), a power supply storage assembly (5), a liftable shielding protection display frame structure (6), a slidable supporting and fixing seat structure (7), a slidable locking storage box structure (8), a liftable rotation testing seat structure (9), a connecting seat (10), a lifting motor assembly (11), a maintenance seat (12), a first U-shaped seat (13), a second U-shaped seat (14), a rotation supporting rod (15), a protective rod (16) and a protective ring (17), wherein the movable brake wheels (2) are respectively bolted at four corners of the lower end of the movable base (1); the protective supply box (3) is connected to the middle position of the right side of the upper end of the movable base (1) through a bolt; the pushing frame (4) is connected to the right side of the upper end of the movable base (1) through bolts and arranged on the right side of the protective supply box (3); the power supply storage component (5) is connected to the middle position of the inner bottom end of the protection supply box (3) through a bolt; the connecting seat (10) is connected to the left side of the middle position of the upper end of the movable base (1) through a bolt; the lifting motor component (11) is connected to the middle position of the upper end of the connecting seat (10) through a bolt; the first U-shaped seats (13) are respectively arranged at the upper ends of the slidable supporting and fixing seat structures (7); the second U-shaped seat (14) is respectively bolted at the middle positions of the left side and the right side of the lower end of the maintenance seat (12); the lower ends of the rotating support rods (15) are respectively connected to the middle position of the inner part of the upper side of the first U-shaped seat (13) in a shaft mode; the upper ends of the rotating support rods (15) are respectively connected to the middle position inside the lower side of the second U-shaped seat (14) in a shaft mode; the lower end of the guard bar (16) is respectively bolted at the periphery of the upper end of the maintenance seat (12); the upper end of the guard rod (16) is respectively bolted at the periphery of the lower end of the guard ring (17); the multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device is characterized in that the liftable shielding protection display frame structure (6) in the multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device is arranged in the middle position inside the upper side of the protection supply box (3); the slidable supporting fixed seat structure (7) is arranged on the left side of the upper end of the movable base (1) and is arranged on the left side of the connecting seat (10); the slidable locking storage box structure (8) is arranged on the outer wall of the upper end of the protection ring (17); the lifting and rotating test seat structure (9) is arranged at the upper end of the sliding locking storage box structure (8); the lifting shielding protection display frame structure (6) comprises a shielding cover (61), a lifting rod (62), a display frame (63), a control display mechanism (64), an L-shaped sliding rod (65) and a first locking nut (66), wherein the lifting rod (62) is connected to the middle position of the upper end of the shielding cover (61) through a bolt; the upper end of the display frame (63) is connected with the middle position of the lower end of the shielding cover (61) through a bolt; the control display mechanism (64) is connected to the middle position of the inner bottom end of the display frame (63) through a bolt; the upper end of the L-shaped sliding rod (65) is respectively bolted at the middle positions of the left side and the right side of the lower end of the shielding cover (61); the first locking nuts (66) are respectively in threaded connection with the outer walls of the left side and the right side of the lower end of the L-shaped sliding rod (65).

2. The multifunctional high altitude electromagnetic field radiation sensitivity automatic testing device as claimed in claim 1, characterized in that the slidable supporting fixed seat structure (7) comprises an inclined L-shaped seat (71), a sliding groove (72), a first pulley (73), a deep groove ball bearing (74), a sliding block (75) and a threaded pipe (76), wherein the sliding groove (72) is arranged on the right side of the upper end of the inclined L-shaped seat (71); the first pulley (73) is sequentially connected to the lower part of the inner wall of the sliding groove (72) in a shaft way from left to right; the deep groove ball bearing (74) is embedded in the middle position of the left side of the inclined L-shaped seat (71); the lower end of the sliding block (75) is inserted at the bottom end of the sliding groove (72) in a sliding manner; the threaded pipe (76) penetrates through the middle position inside the upper end of the sliding block (75) and is arranged in a threaded connection mode; the left end of the threaded pipe (76) is inserted into the inner ring of the deep groove ball bearing (74).

3. The multifunctional high altitude electromagnetic field radiation sensitivity automatic test device according to claim 1, characterized in that the slidable locking storage box structure (8) comprises an inverted U-shaped sliding frame (81), a second pulley (82), a jacking bolt (83), a tool box (84), a hanging plate (85) and a hook (86), wherein the second pulley (82) is sequentially pivoted on the upper part of the inner wall of the inverted U-shaped sliding frame (81) from left to right; the puller bolt (83) is in threaded connection with the middle position of the front surface of the inverted U-shaped sliding frame (81); the tool box (84) is connected to the lower part of the rear surface of the inverted U-shaped sliding frame (81) through bolts; the hanging plate (85) is connected to the middle position of the lower part of the front surface of the inverted U-shaped sliding frame (81) through a bolt; the hooks (86) are sequentially welded in the middle of the front surface of the hanging plate (85) from left to right.

4. The multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device as defined in claim 1, wherein the liftable and rotatable testing seat structure (9) comprises a testing mechanism (91), a testing seat (92), a lifting rod (93), a rotating tube (94), a locking nut (95), a U-shaped frame (96) and a second bolt and nut (97), wherein the testing mechanism (91) is bolted at the middle position of the upper end of the testing seat (92); the upper end of the lifting rod (93) is coupled to the middle position inside the lower end of the test seat (92) in a shaft manner; the lower end of the lifting rod (93) is in threaded connection with the middle position of the upper inner part of the rotating pipe (94); the locking nut (95) is in threaded connection with the upper part of the outer wall of the lifting rod (93); the lower end of the rotating pipe (94) is inserted in the middle of the upper inner part of the U-shaped frame (96); bolts in the second bolt and nut (97) respectively penetrate through the middle inside the upper end of the U-shaped frame (96) and the middle inside the lower end of the rotating pipe (94) and are in threaded connection with the nuts.

5. The multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device as claimed in claim 1, characterized in that a stainless steel rod is inserted in the middle position of the upper end of the pushing frame (4); the connecting seat (10) is arranged in the middle of the lower part of the left side of the protective supply box (3); the protective supply box (3) adopts a stainless steel box with sliding holes arranged in the middle positions of the left side and the right side; the rotating support rods (15) are stainless steel rods and are provided with a plurality of rotating support rods; the rotating support rods (15) are arranged in a shaft connection mode.

6. The multifunctional high altitude electromagnetic field radiation sensitivity automatic testing device as claimed in claim 1, characterized in that the shielding cover (61) is covered and connected with the upper end of the protective supply box (3); the left side and the right side of the lower end of the L-shaped sliding rod (65) respectively penetrate through sliding holes formed in the left and the right joint measurement of the protective supply box (3); the first locking nuts (66) are respectively arranged at the lower parts of the left side and the right side of the protective supply box (3); the display frame (63) and the control display mechanism (64) are arranged in the middle of the upper inner part of the protective supply box (3).

7. The multifunctional high altitude electromagnetic field radiation sensitivity automatic test device according to claim 2, characterized in that the inclined L-shaped seat (71) is bolted at the middle position of the left side of the upper end of the mobile base (1); the right end of the threaded pipe (76) is connected with the outer wall of the output shaft of the lifting motor assembly (11) in a key mode; and the first U-shaped seat (13) is respectively in bolted connection with the middle position of the left side of the upper end of the inclined L-shaped seat (71) and the middle position of the upper end of the sliding block (75).

8. The multifunctional high-altitude electromagnetic field radiation sensitivity automatic testing device as claimed in claim 3, wherein the inverted U-shaped sliding frame (81) is slidably sleeved on the left side of the outer wall of the upper end of the guard ring (17); the lower end of the second pulley (82) is in contact with the upper end of the guard ring (17); the tool box (84) is arranged on the inner wall of the guard bar (16); the hanging plate (85) is arranged on the outer wall of the guard bar (16).

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