CN114400164A

CN114400164A - Vacuum type high-voltage insulation device and stabilizing, driving, protecting and mounting structure thereof

Info

Publication number: CN114400164A
Application number: CN202210189968.8A
Authority: CN
Inventors: 于广; 程羽佳; 祝圣光; 涂立
Original assignee: University of Electronic Science and Technology of China Zhongshan Institute
Current assignee: University of Electronic Science and Technology of China Zhongshan Institute
Priority date: 2022-02-28
Filing date: 2022-02-28
Publication date: 2022-04-26
Anticipated expiration: 2042-02-28
Also published as: CN117936319A; CN118016475A; CN118098870A; CN114400164B

Abstract

The invention discloses a vacuum type high-voltage insulation device and a stabilizing, driving, protecting and mounting structure thereof, belonging to the technical field of high-voltage insulation and belonging to the technical field of high-voltage insulation; the device comprises a stable structure, wherein the stable structure comprises a first supporting plate, a vacuum insulation box, a first high-voltage wire, a second high-voltage wire, a fixed clamping plate, a movable column, an adjusting plate, a reset spring, an eccentric wheel, a transmission shaft and a driving shell, the top of the first supporting plate is fixedly connected with the vacuum insulation box, one side of the vacuum insulation box is connected with the first high-voltage wire, the other side of the vacuum insulation box is connected with the second high-voltage wire, the fixed clamping plate is arranged below the first high-voltage wire and the second high-voltage wire, the fixed clamping plate is fixedly connected to the top of the first supporting plate, the movable clamping plate is arranged above the first high-voltage wire and the second high-voltage wire, the bottom of the movable clamping plate is fixedly connected with the movable column, and the bottom of the movable column is fixedly connected with the adjusting plate; the vacuum type high-voltage insulation device is convenient to mount and dismount and has a protection function.

Description

Vacuum type high-voltage insulation device and stabilizing, driving, protecting and mounting structure thereof

Technical Field

The invention discloses a vacuum type high-voltage insulation device and a stabilizing, driving, protecting and mounting structure thereof, and belongs to the technical field of high-voltage insulation.

Background

High voltage refers to alternating current or direct current with voltage more than 380V but not more than 11kV, insulation, and physical terms, refers to the use of non-conductive material to isolate or wrap up charged body, so as to protect electric shock, good insulation is the most basic and reliable means to ensure the safe operation of electrical equipment and lines, and to prevent personal electric shock accidents, insulation can be generally divided into gas insulation, liquid insulation and solid insulation, in practical application, solid insulation is still the most widely used, and the most reliable one is an insulation material, under the action of strong electricity, the insulation material may be punctured to lose its insulation property, due to corrosive gas, steam, moisture, conductive dust and mechanical operation, the insulation property of the insulation material can be reduced or even destroyed, and the long-term action of environmental factors such as sunlight, wind and rain, the insulating material may also be aged to gradually lose its insulating properties.

Because the cavity environment in the vacuum equipment is the vacuum environment, the probability that the double-electrode structure in the vacuum equipment is subjected to avalanche type electric breakdown is extremely low, in the vacuum environment, the number of gas molecules is extremely small, even if electrons existing in an electrode gap fly to another electrode from one electrode at a high speed under the action of an electric field, the electrons rarely collide with the gas molecules, and therefore the vacuum insulation effect is good, the existing insulation device for high voltage is not convenient to fix the high-voltage wire during installation, the high-voltage wire is easy to loosen or even fall off during use, and the use of the high-voltage wire is influenced.

Disclosure of Invention

In order to solve the not enough of prior art, utilize stable structure can fix the high-voltage line, produce the problem that becomes flexible even drops easily when having solved the high-voltage line and use, and can insulate high voltage system, it is effectual to insulate, the high voltage system's of being convenient for use.

More in order to solve the problem among the prior art, utilize protective structure can protect vacuum formula insulator arrangement isotructure, solved vacuum formula insulator arrangement and suffered the problem that the insulating effect is influenced by the exposure to the sun and rain for a long time, can cushion the thing that falls simultaneously, increase vacuum formula insulator arrangement's life, the use of the vacuum formula insulator arrangement of being convenient for.

Further in order to solve the problems in the prior art, the vacuum type insulating device can be conveniently mounted and dismounted by utilizing the mounting, the problems that the vacuum type insulating device is troublesome to mount and operate and is difficult to dismount are solved, the operation is simple, the mounting and dismounting are convenient, the mounting and dismounting efficiency of the vacuum type insulating device is increased, and the use of the vacuum type insulating device is convenient.

The purpose of the invention is realized as follows:

the vacuum type high-voltage insulation device comprises a stable structure, a driving structure, a protection structure and a mounting structure;

the stabilizing structure comprises a first supporting plate, a vacuum insulation box, a first high-voltage wire, a second high-voltage wire, a fixed clamp plate, a movable column, an adjusting plate, a reset spring, an eccentric wheel, a transmission shaft and a driving shell, wherein the top of the first supporting plate is fixedly connected with the vacuum insulation box, one side of the vacuum insulation box is connected with the first high-voltage wire, the other side of the vacuum insulation box is connected with the second high-voltage wire, the fixed clamp plate is arranged below the first high-voltage wire and the second high-voltage wire, the fixed clamp plate is fixedly connected to the top of the first supporting plate, the movable clamp plate is arranged above the first high-voltage wire and the second high-voltage wire, the bottom of the movable clamp plate is fixedly connected with the movable column, the bottom of the movable column is fixedly connected with the adjusting plate, the top of the adjusting plate is fixedly connected with a plurality of reset springs, the reset springs are fixedly connected to the bottom of the first supporting plate, the top of the adjusting plate is provided with the eccentric wheel, one side of the eccentric wheel is fixedly connected with a transmission shaft, and one end of the transmission shaft is fixedly connected with a driving structure; the top surface of the fixed clamping plate is provided with a plurality of uniformly distributed placing grooves, the bottom of the movable clamping plate is fixedly connected with four movable columns distributed in a rectangular structure, the first supporting plate is provided with a plurality of movable holes, the bottom ends of the movable columns penetrate through the movable holes and are fixedly connected to the top of the adjusting plate, a vacuum cavity is arranged in the vacuum insulation box, two sides of the vacuum insulation box are respectively provided with a connecting port, one end of each of a first high-voltage wire and a second high-voltage wire penetrates through the connecting port and is arranged in the vacuum cavity, and the inner surface and the outer surface of the vacuum insulation box are coated with insulating coatings;

the driving structure comprises a driving shell, a double-shaft motor, a first chain wheel, a driving chain and a second chain wheel, the driving shell is fixedly connected to the bottom of a first supporting plate, the bottom of an inner cavity of the driving shell is fixedly connected with the double-shaft motor, two output ends of the double-shaft motor are fixedly connected with the first chain wheel, the side surface of the first chain wheel is meshed with the driving chain, the driving chain is meshed with the side surface of the second chain wheel, one sides of the first chain wheel and the second chain wheel are fixedly connected with a transmission shaft, two symmetrically distributed rotating holes are formed in the two side surfaces of the driving shell, and one end of the transmission shaft penetrates through the rotating holes and is fixedly connected to one side of the transmission shaft;

the protective structure comprises a support column, a second support plate, a first sliding plate, a one-way threaded column, a sliding column, a second sliding plate, a first connecting column, a second connecting column and a protective cover, wherein the support column is fixedly connected to the bottom of the first support plate, the bottom end of the support column is fixedly connected with the second support plate, the surface of the support column is slidably connected with the first sliding plate, the first sliding plate is in threaded connection with the surface of the one-way threaded column, one end of the one-way threaded column is fixedly connected with a transmission component, the top of the first sliding plate is fixedly connected with the sliding column, the top end of the sliding column is fixedly connected with the second sliding plate, one side of the second sliding plate is fixedly connected with the first connecting column, one adjacent side of the second sliding plate is fixedly connected with the second connecting column, the top of the second sliding plate is fixedly connected with a buffer component, and the top of the buffer component is fixedly connected with the protective cover;

mounting structure includes fixed casing, reference column, reinforcing plate, mounting panel, two-way screw post, erection column and antiskid grip block, fixed casing rigid coupling is in second backup pad bottom, fixed casing one side rigid coupling has the reference column, reference column one end rigid coupling has the reinforcing plate, the reinforcing plate rigid coupling is in second backup pad bottom, reinforcing plate surface sliding connection mounting panel, mounting panel threaded connection is on two-way screw post surface, two-way screw post one end rigid coupling has power component, mounting panel bottom rigid coupling erection column, erection column bottom rigid coupling antiskid grip block.

Above-mentioned vacuum type high voltage insulation device, second backup pad top rigid coupling has four support columns that are the distribution of rectangle structure, four spacing holes that are the distribution of rectangle structure are seted up to first sliding plate, spacing hole and rigid coupling are run through in first backup pad bottom to the support column top, first sliding plate top rigid coupling has four sliding columns that are the distribution of rectangle structure, four sliding holes that are the distribution of rectangle structure are seted up to first backup pad, sliding column top runs through sliding hole and extends to first backup pad top, the equal rigid coupling in first spliced pole and second spliced pole both ends has the second sliding plate, and four the second sliding plate is the distribution of rectangle structure.

Above-mentioned vacuum type high voltage insulation device, second backup pad bottom rigid coupling has the reinforcing plate of two symmetric distributions, and two the equal rigid coupling in one side that the reinforcing plate is close to fixed casing has the reference column of two symmetric distributions, reference column surface sliding connection has the mounting panel of two symmetric distributions, the locating hole of two symmetric distributions is seted up to the mounting panel, locating hole and rigid coupling are run through to reference column one end in fixed casing one side, threaded hole is seted up to the mounting panel, two-way screw post one end runs through the screw hole and rotates to be connected in reinforcing plate one side, mounting panel bottom rigid coupling has the erection column of two symmetric distributions, antiskid grip block one side rigid coupling has a plurality of antislip strip.

In the vacuum type high-voltage insulating apparatus described above,

the transmission assembly comprises a transmission shell, a rotating handle, a third chain wheel, a transmission chain and a fourth chain wheel, the transmission shell is fixedly connected with the bottom of the second supporting plate, the bottom surface of the transmission shell is rotationally connected with the rotating handle, the top end of the rotating handle is rotatably connected with a third chain wheel, the side surface of the third chain wheel is meshed and connected with a transmission chain, the transmission chain is meshed and connected with the side surface of a fourth chain wheel, the top surfaces of the third chain wheel and the fourth chain wheel are fixedly connected with one-way threaded columns, the second supporting plate is provided with two symmetrically distributed mounting holes, the top end of the one-way threaded column penetrates through the mounting hole and is rotatably connected with the bottom surface of the first supporting plate, the bottom surfaces of the third chain wheel and the fourth chain wheel are fixedly connected with rotating handles, the bottom surface of the transmission shell is provided with two preset holes which are symmetrically distributed, and the top end of the rotating handle penetrates through the preset holes and extends to the inner cavity of the transmission shell;

the buffer assembly comprises a fixed column, a limiting plate, a buffer spring and a buffer sleeve, the fixed column is fixedly connected to the top of the second sliding plate, the top end of the fixed column is fixedly connected with the limiting plate, the top surface of the limiting plate is fixedly connected with the buffer spring, the top end of the buffer spring is fixedly connected to the inner wall of the top surface of the buffer sleeve, the buffer sleeve is fixedly connected to the inner wall of the protective cover, the cross section of the protective cover is of an arc structure, four buffer sleeves distributed in a rectangular structure are fixedly connected to the inner wall of the protective cover, the bottom surface of the buffer sleeve is provided with buffer holes, and the diameter of each buffer hole is larger than that of the fixed column and smaller than the inner diameter of the buffer sleeve;

the power component comprises a single-shaft motor, a main chain wheel, an installation chain and an auxiliary chain wheel, the single-shaft motor is fixedly connected to the inner cavity side wall of the fixed shell, the output end of the single-shaft motor is fixedly connected to the main chain wheel, the main chain wheel is connected to the side face of the main chain wheel in a meshed mode, the installation chain is connected to the side face of the auxiliary chain wheel in a meshed mode, the main chain wheel and the auxiliary chain wheel are fixedly connected to one side of a two-way threaded column, two symmetrically distributed communication ports are formed in one side of the fixed shell, and one end of the two-way threaded column penetrates through the communication ports and is connected to one side of the reinforcing plate in a rotating mode.

The stable structure of the vacuum type high-voltage insulation device comprises a first supporting plate, a vacuum insulation box, a first high-voltage wire, a second high-voltage wire, a fixed clamp plate, a movable column, an adjusting plate, a reset spring, an eccentric wheel, a transmission shaft and a driving shell, wherein the top of the first supporting plate is fixedly connected with the vacuum insulation box, one side of the vacuum insulation box is connected with the first high-voltage wire, the other side of the vacuum insulation box is connected with the second high-voltage wire, the fixed clamp plate is arranged below the first high-voltage wire and the second high-voltage wire, the fixed clamp plate is fixedly connected to the top of the first supporting plate, the movable clamp plate is arranged above the first high-voltage wire and the second high-voltage wire, the bottom of the movable clamp plate is fixedly connected with the movable column, the bottom of the movable column is fixedly connected with the adjusting plate, the top of the adjusting plate is fixedly connected with a plurality of reset springs, the reset springs are fixedly connected to the bottom of the first supporting plate, an eccentric wheel is arranged at the top of the adjusting plate, one side of the eccentric wheel is fixedly connected with a transmission shaft, and one end of the transmission shaft is fixedly connected with a driving structure; fixed splint top surface is seted up a plurality of evenly distributed's standing groove, movable splint bottom rigid coupling has four removal posts that are the distribution of rectangle structure, a plurality of removal hole has been seted up to first backup pad, it runs through removal hole and rigid coupling in regulating plate top to remove the toe end, the inside vacuum chamber that is of vacuum insulation box, vacuum insulation box both sides all are provided with connection port, first high-voltage line and second high-voltage line one end are equallyd divide and are do not penetrated and set up in the vacuum chamber from connection port, vacuum insulation box inner surface and surface all coat have insulating coating.

Vacuum type high voltage insulation device's drive structure, including drive shell, double-shaft motor, first sprocket, drive chain and second sprocket, drive shell rigid coupling is in first backup pad bottom, drive shell inner chamber bottom rigid coupling double-shaft motor, the equal rigid coupling of two outputs of double-shaft motor has first sprocket, drive chain is connected in the meshing of first sprocket side, the meshing of drive chain is connected in second sprocket side, the equal rigid coupling in first sprocket and second sprocket one side has the transmission shaft, just two symmetric distribution's rotation hole has all been seted up to drive shell both sides face, transmission shaft one end runs through rotation hole and rigid coupling in transmission shaft one side.

Vacuum type high voltage insulation device's protective structure, including support column, second backup pad, first sliding plate, one-way screw post, slip post, second sliding plate, first spliced pole, second spliced pole and protective cover, the support column rigid coupling is in first backup pad bottom, support column bottom rigid coupling second backup pad, support column surface sliding connection first sliding plate, first sliding plate threaded connection is on one-way screw post surface, one-way screw post one end rigid coupling has drive assembly, first sliding plate top rigid coupling slip post, slip capital end rigid coupling second sliding plate, the first spliced pole of second sliding plate one side rigid coupling, the adjacent one side rigid coupling second spliced pole of second sliding plate, second sliding plate top rigid coupling has the buffering subassembly, buffering subassembly top rigid coupling has the protective cover.

The protection structure of the vacuum type high voltage insulation device,

the buffer assembly comprises a fixed column, a limiting plate, a buffer spring and a buffer sleeve, the fixed column is fixedly connected to the top of the second sliding plate, the top end of the fixed column is fixedly connected to the limiting plate, the top end of the limiting plate is fixedly connected to the buffer spring, the top end of the buffer spring is fixedly connected to the inner wall of the top surface of the buffer sleeve, the buffer sleeve is fixedly connected to the inner wall of the protective cover, the cross section of the protective cover is of an arc-shaped structure, four buffer sleeves distributed in a rectangular structure are fixedly connected to the inner wall of the protective cover, a buffer hole is formed in the bottom surface of the buffer sleeve, and the diameter of the buffer hole is larger than that of the fixed column and smaller than the inner diameter of the buffer sleeve.

Vacuum type high voltage insulation device's mounting structure, including fixed casing, reference column, reinforcing plate, mounting panel, two-way screw post, erection column and antiskid grip block, fixed casing rigid coupling is in second backup pad bottom, fixed casing one side rigid coupling has the reference column, reference column one end rigid coupling has the reinforcing plate, the reinforcing plate rigid coupling is in second backup pad bottom, reinforcing plate surface sliding connection mounting panel, mounting panel threaded connection is on two-way screw post surface, two-way screw post one end rigid coupling has power component, mounting panel bottom rigid coupling erection column, erection column bottom rigid coupling antiskid grip block.

Above-mentioned vacuum type high voltage insulation device's mounting structure, power component includes unipolar motor, main chain wheel, installation chain and vice sprocket, unipolar motor rigid coupling is in fixed casing inner chamber lateral wall, unipolar motor's output rigid coupling main chain wheel, main chain wheel side meshing connects the installation chain, the meshing of installation chain is connected in vice sprocket side, just the equal rigid coupling in main chain wheel and vice sprocket one side has two-way screw thread post, fixed casing one side is seted up the intercommunication mouth of two symmetric distributions, two-way screw thread post one end is run through the intercommunication mouth and is rotated and connect in reinforcing plate one side.

The invention discloses a vacuum type high-voltage insulation device and a vacuum type high-voltage insulation device, which have the following beneficial effects:

first, the vacuum type high voltage insulation device of the present invention can fix a high voltage line by using a stable structure, solves the problem that the high voltage line is easy to loosen or even fall off when in use, can insulate a high voltage system, has a good insulation effect, and is convenient for the use of the high voltage system.

Secondly, the vacuum type high-voltage insulation device can protect structures such as the vacuum type insulation device by using the protection structure, solves the problem that the vacuum type insulation device is exposed to the sun and rain for a long time to influence the insulation effect, can buffer falling objects, prolongs the service life of the vacuum type insulation device, and is convenient for the use of the vacuum type insulation device.

Thirdly, the vacuum type high-voltage insulation device can be conveniently installed and disassembled by installation, the problems that the vacuum type insulation device is troublesome to install and operate and difficult to disassemble are solved, the operation is simple, the installation and the disassembly are convenient, the installation and the disassembly efficiency of the vacuum type insulation device are improved, and the use of the vacuum type insulation device is convenient.

Drawings

FIG. 1 is a schematic perspective view of a vacuum type high voltage insulation apparatus according to the present invention;

FIG. 2 is a schematic cross-sectional view of a vacuum type high voltage insulation device according to the present invention;

FIG. 3 is a side view schematic of a stabilization construct;

FIG. 4 is a schematic structural diagram of the positional relationship among the dual-shaft motor, the first sprocket, the driving chain, the second sprocket, the transmission shaft and the eccentric wheel;

FIG. 5 is a structural diagram showing the positional relationship between the rotating handle, the third sprocket, the driving chain, the fourth sprocket and the unidirectional threaded post;

FIG. 6 is a structural diagram showing the positional relationship among the support column, the first slide plate and the slide column;

FIG. 7 is a structural diagram illustrating the positional relationship between the second sliding plate, the first connecting post, the second connecting post and the sliding post;

FIG. 8 is a schematic view of the internal structure of the cushioning assembly;

FIG. 9 is a schematic view showing the positional relationship among the stationary housing, the positioning post, the reinforcing plate and the two-way threaded post;

fig. 10 is a schematic view of the positional relationship between the stationary housing, the single-shaft motor, the main sprocket, the mounting chain, the sub-sprocket, and the bidirectional threaded post.

In the figure: 1. a first support plate; 2. a vacuum insulation box; 3. a first high-voltage line; 4. a second high-voltage line; 5. fixing the clamping plate; 6. moving the clamping plate; 7. moving the column; 8. an adjusting plate; 9. a return spring; 10. an eccentric wheel; 11. a drive shaft; 12. a drive housing; 13. a double-shaft motor; 14. a first sprocket; 15. a drive chain; 16. a second sprocket; 17. a support pillar; 18. a second support plate; 19. a first sliding plate; 20. a one-way threaded post; 21. a sliding post; 22. a second sliding plate; 23. a first connecting column; 24. a second connecting column; 25. a protective cover; 26. a transmission housing; 27. rotating the handle; 28. a third sprocket; 29. a drive chain; 30. a fourth sprocket; 31. fixing a column; 32. a limiting plate; 33. a buffer spring; 34. a buffer sleeve; 35. a stationary housing; 36. a positioning column; 37. a reinforcing plate; 38. mounting a plate; 39. a bi-directional threaded post; 40. mounting a column; 41. an anti-slip clamping plate; 42. a single-shaft motor; 43. a main sprocket; 44. installing a chain; 45. and a secondary sprocket.

Detailed Description

In order to make the objects, features and advantages of the present application more apparent and understandable, the embodiments of the present application will be described in detail and fully with reference to the accompanying drawings. All other embodiments that can be derived by a person skilled in the art from the detailed description of the embodiments given herein without making any creative effort belong to the protection scope of the present application.

The technical scheme of the application is further explained by the specific implementation mode in combination with the attached drawings.

In the description of the present application, it is to be understood that the terms "upper", "lower", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing the present application and simplifying the description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present application.

Detailed description of the invention

The following is a specific embodiment of the vacuum type high voltage insulation device of the present invention.

The vacuum type high-voltage insulation device in the embodiment, referring to fig. 1 to 2, comprises a stable structure, the stable structure comprises a first support plate 1, a vacuum insulation box 2, a first high-voltage wire 3, a second high-voltage wire 4, a fixed clamp plate 5, a movable clamp plate 6, a movable column 7, an adjusting plate 8, a reset spring 9, an eccentric wheel 10, a transmission shaft 11 and a driving shell 12, the top of the first support plate 1 is fixedly connected with the vacuum insulation box 2, one side of the vacuum insulation box 2 is connected with the first high-voltage wire 3, the other side of the vacuum insulation box 2 is connected with the second high-voltage wire 4, the fixed clamp plate 5 is arranged below the first high-voltage wire 3 and the second high-voltage wire 4, the fixed clamp plate 5 is fixedly connected to the top of the first support plate 1, the movable clamp plate 6 is arranged above the first high-voltage wire 3 and the second high-voltage wire 4, the bottom of the movable clamp plate 6 is fixedly connected with the movable column 7, the bottom of the movable column 7 is fixedly connected with the adjusting plate 8, the top of the adjusting plate 8 is fixedly connected with a plurality of return springs 9, the return springs 9 are fixedly connected to the bottom of the first supporting plate 1, the top of the adjusting plate 8 is provided with an eccentric wheel 10, one side of the eccentric wheel 10 is fixedly connected with a transmission shaft 11, and one end of the transmission shaft 11 is fixedly connected with a driving structure.

Through the technical scheme, the high-voltage wire can be fixed by utilizing the stable structure, the high-voltage wire is prevented from being easily loosened and even falling off when in use, and the high-voltage system can be insulated, the insulation effect is good, the use of the high-voltage system is convenient, the first high-voltage wire 3 and the second high-voltage wire 4 are respectively arranged at two sides of the vacuum insulation box 2 when in use, the first high-voltage wire 3 and the second high-voltage wire 4 are respectively placed above the fixed clamping plate 5, then the driving structure is utilized to drive the transmission shaft 11 to rotate, so as to drive the eccentric wheel 10 to rotate, the eccentric wheel 10 can drive the adjusting plate 8 to move downwards when rotating, so as to drive the movable column 7 to move in the same direction, the movable clamping plate 6 can be driven to move in the same direction when the movable column 7 moves, so as to respectively fix the first high-voltage wire 3 and the second high-voltage wire 4 by utilizing the movable clamping plate 6 and the fixed clamping plate 5, and the first high-voltage wire 3 and the second high-voltage wire 4 are prevented from being loosened and even falling off when in use, prevent to influence vacuum type insulating device's use, when first high-voltage line 3 and second high-voltage line 4 need be dismantled, utilize opposite mode to rotate eccentric wheel 10, at this moment under reset spring 9's effect, eccentric wheel 10 regulating plate 8 and removal splint 6 isotructure can reply initial position, are convenient for dismantle first high-voltage line 3 and second high-voltage line 4 this moment.

As a further optimization scheme, as shown in fig. 4, the driving structure includes a driving housing 12, a dual-shaft motor 13, a first sprocket 14, a driving chain 15 and a second sprocket 16, the driving housing 12 is fixedly connected to the bottom of the first supporting plate 1, the bottom of the inner cavity of the driving housing 12 is fixedly connected to the dual-shaft motor 13, two output ends of the dual-shaft motor 13 are fixedly connected to the first sprocket 14, the side surface of the first sprocket 14 is engaged with the driving chain 15, the driving chain 15 is engaged with the side surface of the second sprocket 16, one sides of the first sprocket 14 and the second sprocket 16 are fixedly connected to the transmission shaft 11, two side surfaces of the driving housing 12 are respectively provided with two symmetrically distributed rotation holes, one end of the transmission shaft 11 penetrates through the rotation holes and is fixedly connected to one side of the transmission shaft 11, when in use, the dual-shaft motor 13 drives the first sprocket 14 to rotate, thereby driving the driving chain 15 to rotate, and further driving the second sprocket 16 to rotate, and when the first sprocket 14 and the second sprocket 16 rotate, the corresponding transmission shaft 11 can be driven to rotate, thereby driving the eccentric wheel 10 to rotate.

Particularly, as shown in fig. 2 and 3, a plurality of evenly distributed's standing groove is seted up to solid fixed splint 5 top surface, can be convenient for place first high-voltage line 3 or second high-voltage line 4 through the standing groove, the rigid coupling of movable splint 6 bottom has four removal post 7 that are the distribution of rectangular structure, a plurality of removal hole has been seted up to first backup pad 1, remove 7 bottom of post and run through removal hole and rigid coupling in 8 tops of regulating plate, the inside vacuum chamber that is of

vacuum insulation box

2, 2 both sides of vacuum insulation box all are provided with connection port, first high-

voltage line

3 and 4 one ends of second high-voltage line are equallyd divide and are penetrated and set up in the vacuum chamber from connection port respectively, 2 internal surfaces of vacuum insulation box and surface all coat have insulating coating, can improve the insulating effect of high voltage through vacuum insulation box 2.

As an optimization, as shown in fig. 2, comprises a guard structure, which comprises a support column 17, a second support plate 18, a first sliding plate 19, a one-way threaded column 20, sliding column 21, second sliding plate 22, first connecting column 23, second connecting column 24 and protective cover 25, support column 17 rigid coupling in 1 bottom of first backup pad, support column 17 bottom rigid coupling second backup pad 18, support column 17 surface sliding connection first sliding

plate

19, 19 threaded connection in one-way screw post 20 surfaces of first sliding plate, 20 one end rigid couplings of one-way screw post have drive assembly, 19 top rigid coupling sliding columns 21 of first sliding plate, 21 top rigid coupling second sliding plate 22 of sliding column, 22 one side rigid coupling first connecting column 23 of second sliding plate, the adjacent one side rigid coupling second connecting column 24 of second sliding

plate

22, 22 top rigid couplings of second sliding plate have buffering subassembly, buffering subassembly top rigid coupling has protective cover 25.

Through the technical scheme, the vacuum type insulating device and other structures can be protected by using the protection structure, the vacuum type insulating device is prevented from being exposed to the sun and rain for a long time to influence the insulating effect, meanwhile, falling objects can be buffered, the service life of the vacuum type insulating device is prolonged, the use of the vacuum type insulating device is convenient, after the first high-voltage wire 3 and the second high-voltage wire 4 are installed, the rotating handle 27 is rotated to drive the third chain wheel 28 to rotate, further, the transmission chain 29 is driven to rotate, further, the fourth chain wheel 30 is driven to rotate, the third chain wheel 28 and the fourth chain wheel 30 can drive the one-way threaded columns 20 at the two sides to rotate at the same time when rotating, the one-way threaded columns 20 can drive the first sliding plate 19 to move downwards along the supporting columns 17, further, the sliding columns 21 are driven to move in the same direction, further, the second sliding plate 22 and other structures are driven to move in the same direction, further, the protection cover 25 is driven to move downwards, utilize protective cover 25 to cover vacuum insulation box 2 isotructures, protective cover 25 can protect vacuum insulation box 2 isotructures, prevent that vacuum insulation box 2 from suffering the sun and rain and drenching and influence insulating effect, then utilize buffer structure, make protective cover 25 can cushion the thing that falls, prevent that the thing that falls from smashing vacuum insulation box 2, prevent to influence vacuum type insulator arrangement's life.

Specifically, as shown in fig. 6 and 7, the top of the second support plate 18 is fixedly connected with four support columns 17 distributed in a rectangular structure, the first sliding plate 19 is provided with four limiting holes distributed in a rectangular structure, the top of the support column 17 penetrates through the limiting holes and is fixedly connected to the bottom of the first support plate 1, the support column 17 can limit the moving track of the first sliding plate 19 in an equal structure, the top of the first sliding plate 19 is fixedly connected with four sliding columns 21 distributed in a rectangular structure, the first support plate 1 is provided with four sliding holes distributed in a rectangular structure, the top of the sliding column 21 penetrates through the sliding holes and extends to the top of the first support plate 1, the two ends of the first connecting column 23 and the two ends of the second connecting column 24 are fixedly connected with the second sliding plate 22, and the four second sliding plates 22 are distributed in a rectangular structure.

As a further optimization scheme, as shown in fig. 5, the transmission assembly includes a transmission housing 26, a rotation handle 27, a third sprocket 28, a transmission chain 29 and a fourth sprocket 30, the transmission housing 26 is fixedly connected to the bottom of the second support plate 18, the bottom surface of the transmission housing 26 is rotatably connected to the rotation handle 27, the top end of the rotation handle 27 is rotatably connected to the third sprocket 28, the side surface of the third sprocket 28 is engaged with the transmission chain 29, the transmission chain 29 is engaged with the side surface of the fourth sprocket 30, the top surfaces of the third sprocket 28 and the fourth sprocket 30 are both fixedly connected to the one-way threaded post 20, the second support plate 18 is provided with two symmetrically distributed mounting holes, the top end of the one-way threaded post 20 penetrates through the mounting hole and is rotatably connected to the bottom surface of the first support plate 1, the bottom surfaces of the third sprocket 28 and the fourth sprocket 30 are both fixedly connected to the rotation handle 27, the bottom surface of the transmission housing 26 is provided with two symmetrically distributed preset holes, the top end of the rotating handle 27 penetrates through the preset hole and extends to the inner cavity of the transmission shell 26, and the rotating handle 27 is rotated when the transmission device is used, so that the third chain wheel 28 is driven to rotate, the transmission chain 29 is driven to rotate, the fourth chain wheel 30 is driven to rotate, and the third chain wheel 28 and the fourth chain wheel 30 can drive the one-way threaded columns 20 on the two sides to rotate simultaneously when rotating.

As a further optimization scheme, as shown in fig. 8, the buffering component includes a fixing column 31, a limiting plate 32, a buffering spring 33 and a buffering sleeve 34, the fixing column 31 is fixedly connected to the top of the second sliding plate 22, the top end of the fixing column 31 is fixedly connected to the limiting plate 32, the top surface of the limiting plate 32 is fixedly connected to the buffering spring 33, the top end of the buffering spring 33 is fixedly connected to the inner wall of the top surface of the buffering sleeve 34, the buffering sleeve 34 is fixedly connected to the inner wall of the protecting cover 25, the cross section of the protecting cover 25 is in an arc structure, four buffer sleeves 34 distributed in a rectangular structure are fixedly connected to the inner wall of the protective cover 25, the bottom surface of each buffer sleeve 34 is provided with a buffer hole, the diameter of each buffer hole is larger than that of the fixed column 31 and smaller than the inner diameter of each buffer sleeve 34, when the vacuum insulation device is used, when the protective cover 25 is impacted by a falling object, the impact force can be buffered through the structures such as the buffer spring 33, and the service life of the vacuum insulation device is prolonged.

As an optimization scheme, as shown in fig. 2, the anti-skidding clamping device comprises a mounting structure, the mounting structure comprises a fixed casing 35, a positioning column 36, a reinforcing plate 37, a mounting plate 38, a two-way threaded column 39, a mounting column 40 and an anti-skidding clamping plate 41, the fixed casing 35 is fixedly connected to the bottom of the second support plate 18, the positioning column 36 is fixedly connected to one side of the fixed casing 35, the reinforcing plate 37 is fixedly connected to one end of the positioning column 36, the reinforcing plate 37 is fixedly connected to the bottom of the second support plate 18, the surface of the reinforcing plate 37 is slidably connected to the mounting plate 38, the mounting plate 38 is in threaded connection with the surface of the two-way threaded column 39, a power assembly is fixedly connected to one end of the two-way threaded column 39, the mounting column 40 is fixedly connected to the bottom of the mounting plate 38, and the anti-skidding clamping plate 41 is fixedly connected to the bottom end of the mounting column 40.

Through the technical scheme, the installation and the dismantlement of vacuum type insulator arrangement of can being convenient for are utilized in the installation, increase the installation of vacuum type insulator arrangement, the efficiency of dismantlement, the use of the vacuum type insulator arrangement of being convenient for, when using, utilize power component to drive two-way screw thread post 39 and rotate, can drive the reference column 36 equidirectional removal of both sides when two-way screw thread post 39 rotates, thereby drive erection column 40 equidirectional removal, and then drive the antiskid grip block 41 equidirectional removal of both sides, utilize the antiskid grip block 41 of both sides to carry out the centre gripping to the stationary part, moreover, the steam generator is simple in operation, the installation is stable, and can make the antiskid grip block 41 of both sides remove back and forth through opposite mode, thereby dismantle vacuum type insulator arrangement, be convenient for vacuum type insulator arrangement's installation and dismantlement.

Specifically, as shown in fig. 9, the bottom of the second supporting plate 18 is fixedly connected with two symmetrically distributed reinforcing plates 37, and two reinforcing plates 37 are close to the positioning columns 36 symmetrically distributed on one side of the fixed casing 35, the positioning columns 36 are connected with two symmetrically distributed mounting plates 38 in a surface sliding manner, the mounting plates 38 are provided with two symmetrically distributed positioning holes, one ends of the positioning columns 36 penetrate through the positioning holes and are fixedly connected to one side of the fixed casing 35, the positioning columns 36 can limit the moving track of the mounting plates 38 in an equal structure, the mounting plates 38 are provided with threaded holes, one ends of the bidirectional threaded columns 39 penetrate through the threaded holes and are rotatably connected to one side of the reinforcing plates 37, the mounting plates 38 are fixedly connected with two symmetrically distributed mounting columns 40, the non-slip clamping plates 41 are fixedly connected to one side of a plurality of non-slip strips, and the non-slip strips can make the installation of the vacuum type insulating device more stable.

As a further optimized proposal, as shown in fig. 10, the power assembly comprises a single-shaft motor 42, a main chain wheel 43, a mounting chain 44 and an auxiliary chain wheel 45, the single-shaft motor 42 is fixedly connected with the side wall of the inner cavity of the fixed shell 35, the output end of the single-shaft motor 42 is fixedly connected with the main chain wheel 43, the side surface of the main chain wheel 43 is engaged and connected with the mounting chain 44, the mounting chain 44 is engaged and connected with the side surface of the auxiliary chain wheel 45, and one side of the main chain wheel 43 and one side of the auxiliary chain wheel 45 are both fixedly connected with two-way threaded columns 39, one side of the fixed shell 35 is provided with two symmetrically distributed communicating ports, one end of each two-way threaded column 39 penetrates through the communicating port and is rotatably connected with one side of the reinforcing plate 37, in use, the single-shaft motor 42 can drive the main chain wheel 43 to rotate, thereby driving the mounting chain 44 to rotate, and then the auxiliary chain wheel 45 is driven to rotate, and the main chain wheel 43 and the auxiliary chain wheel 45 can drive the bidirectional threaded column 39 to rotate when rotating, so that the position of the antiskid clamping plate 41 is adjusted.

Detailed description of the invention

The following is a stable structural embodiment of the vacuum type high voltage insulation device of the present invention.

The stable structure of the vacuum type high-voltage insulation device in this embodiment, referring to fig. 1 to 2, comprises a first support plate 1, a vacuum insulation box 2, a first high-voltage wire 3, a second high-voltage wire 4, a fixed clamp plate 5, a movable clamp plate 6, a movable column 7, an adjusting plate 8, a return spring 9, an eccentric wheel 10, a transmission shaft 11 and a driving housing 12, wherein the top of the first support plate 1 is fixedly connected with the vacuum insulation box 2, one side of the vacuum insulation box 2 is connected with the first high-voltage wire 3, the other side of the vacuum insulation box 2 is connected with the second high-voltage wire 4, the fixed clamp plate 5 is arranged below the first high-voltage wire 3 and the second high-voltage wire 4, the fixed clamp plate 5 is fixedly connected to the top of the first support plate 1, the movable clamp plate 6 is arranged above the first high-voltage wire 3 and the second high-voltage wire 4, the bottom of the movable clamp plate 6 is fixedly connected with the movable column 7, an adjusting plate 8 is fixedly connected to the bottom end of the moving column 7, a plurality of reset springs 9 are fixedly connected to the top of the adjusting plate 8, the reset springs 9 are fixedly connected to the bottom of the first supporting plate 1, an eccentric wheel 10 is arranged on the top of the adjusting plate 8, a transmission shaft 11 is fixedly connected to one side of the eccentric wheel 10, and a driving structure is fixedly connected to one end of the transmission shaft 11; fixed splint 5 top surface is seted up a plurality of evenly distributed's standing groove, 6 bottom rigid couplings of movable splint have four removal posts 7 that are the distribution of rectangle structure, a plurality of removal hole has been seted up to first backup pad 1, remove 7 bottoms of post and run through removal hole and rigid coupling in regulating plate 8 tops, 2 inside vacuum chambers that are of vacuum insulation box, 2 both sides of vacuum insulation box all are provided with connection port, first high-voltage wire 3 and 4 one ends of second high-voltage wire are equallyd divide and are do not penetrated and set up in the vacuum chamber from connection port, 2 internal surfaces of vacuum insulation box and surface all coat have insulating coating.

Detailed description of the invention

The following is a specific embodiment of the driving structure of the vacuum type high voltage insulation device of the present invention.

This vacuum type high voltage insulation device's under embodiment drive structure, refer to fig. 4, including drive casing 12, double-shaft motor 13, first sprocket 14, drive chain 15 and second sprocket 16, drive casing 12 rigid coupling in 1 bottom of first backup pad, 12 inner chamber bottom rigid coupling double-shaft motor 13 of drive casing, two equal rigid couplings of output of double-shaft motor 13 have first sprocket 14, drive chain 15 is connected in the meshing of first sprocket 14 side, drive chain 15 meshing is connected in second sprocket 16 side, the equal rigid coupling in first sprocket 14 and second sprocket 16 one side has transmission shaft 11, just two symmetric distribution's rotation hole has all been seted up to drive casing 12 both sides face, 11 one end of transmission shaft runs through rotation hole and rigid coupling in transmission shaft 11 one side.

Detailed description of the invention

The following is a specific embodiment of the protective structure of the vacuum type high voltage insulation device of the present invention.

The protection structure of the vacuum type high voltage insulation device in this embodiment, referring to fig. 2, includes a support pillar 17, a second support plate 18, a first sliding plate 19, a unidirectional threaded pillar 20, a sliding pillar 21, a second sliding plate 22, a first connecting pillar 23, a second connecting pillar 24, and a protective cover 25, the support pillar 17 is fixedly connected to the bottom of the first support plate 1, the bottom end of the support pillar 17 is fixedly connected to the second support plate 18, the surface of the support pillar 17 is slidably connected to the first sliding plate 19, the first sliding plate 19 is threadedly connected to the surface of the unidirectional threaded pillar 20, one end of the unidirectional threaded pillar 20 is fixedly connected to a transmission component, the top of the first sliding plate 19 is fixedly connected to the sliding pillar 21, the top end of the sliding pillar 21 is fixedly connected to the second sliding plate 22, one side of the second sliding plate 22 is fixedly connected to the first connecting pillar 23, and the adjacent side of the second sliding plate 22 is fixedly connected to the second connecting pillar 24, the top of the second sliding plate 22 is fixedly connected with a buffering component, and the top of the buffering component is fixedly connected with a protective cover 25.

Detailed description of the invention

The protection structure of the vacuum type high-voltage insulating device in this embodiment is further defined on the basis of the fourth embodiment:

the transmission assembly, refer to fig. 5, includes transmission housing 26, rotation handle 27, third sprocket 28, drive chain 29 and fourth sprocket 30, transmission housing 26 rigid coupling is in second backup pad 18 bottom, transmission housing 26 bottom surface rotates with rotation handle 27 to be connected, rotation handle 27 top rotates connects third sprocket 28, drive chain 29 is connected in the meshing of third sprocket 28 side, drive chain 29 meshing is connected in fourth sprocket 30 side, just the equal rigid coupling of third sprocket 28 and fourth sprocket 30 top surface has one-way screw post 20, second backup pad 18 has seted up two symmetric distribution's mounting hole, one-way screw post 20 top runs through the mounting hole and rotates to be connected in first backup pad 1 bottom surface, the equal rigid coupling of third sprocket 28 and fourth sprocket 30 bottom surface has rotation handle 27, transmission housing 26 bottom surface has seted up two symmetric distribution's the hole of predetermineeing, the top end of the rotating handle 27 penetrates through a preset hole and extends to the inner cavity of the transmission shell 26;

the buffering subassembly, refer to fig. 8, including fixed column 31, limiting plate 32, buffer spring 33 and buffering sleeve 34, fixed column 31 rigid coupling is at the 22 tops of second sliding plate, fixed column 31 top rigid coupling limiting plate 32, limiting plate 32 top surface rigid coupling buffer spring 33, buffer spring 33 top rigid coupling is in buffering sleeve 34 top surface inner wall, buffering sleeve 34 rigid coupling is in protective cover 25 inner wall, protective cover 25's cross-section is the arc structure, just protective cover 25 inner wall rigid coupling has four to be the buffering sleeve 34 that the rectangle structure distributes, the buffering hole has been seted up to buffering sleeve 34 bottom surface, the diameter in buffering hole is greater than fixed column 31's diameter and is less than the internal diameter of buffering sleeve 34.

Detailed description of the invention

The following is a specific embodiment of the mounting structure of the vacuum type high voltage insulation device of the present invention.

Vacuum type high voltage insulation device mounting structure under this embodiment refers to fig. 2, including fixed casing 35, reference column 36, reinforcing plate 37, mounting panel 38, two-way screw post 39, erection column 40 and anti-skidding grip block 41, fixed casing 35 rigid coupling is in second backup pad 18 bottom, fixed casing 35 one side rigid coupling has reference column 36, reference column 36 one end rigid coupling has reinforcing plate 37, reinforcing plate 37 rigid coupling is in second backup pad 18 bottom, reinforcing plate 37 sliding surface connection mounting panel 38, mounting panel 38 threaded connection is in two-way screw post 39 surfaces, two-way screw post 39 one end rigid coupling has power component, mounting panel 38 bottom rigid

coupling erection column

40, 40 bottom rigid coupling anti-skidding grip block 41 of erection column.

Detailed description of the invention

The vacuum type high-voltage insulating device mounting structure according to the fifth embodiment is further defined on the basis of the sixth embodiment:

the power assembly, refer to fig. 10, including unipolar motor 42, main chain wheel 43, installation chain 44 and vice sprocket 45, unipolar motor 42 rigid coupling is in fixed casing 35 inner chamber lateral wall, unipolar motor 42's output rigid coupling main chain wheel 43, main chain wheel 43 side meshing connects installation chain 44, installation chain 44 meshing connects in vice sprocket 45 side, just main chain wheel 43 and the equal rigid coupling in vice sprocket 45 one side have two-way screw post 39, the intercommunication mouth of two symmetric distributions is seted up to fixed casing 35 one side, two-way screw post 39 one end is run through the intercommunication mouth and is rotated and connect in reinforcing plate 37 one side.

It will be evident to those skilled in the art that the present application is not limited to the details of the foregoing illustrative embodiments, and that the present application may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the application being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

As described above, the above embodiments are only used for illustrating the technical solutions of the present application, and are not limited thereto; although the present application has been described in detail with reference to the foregoing specific embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may be modified or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present application.

Claims

1. The vacuum type high-voltage insulation device is characterized by comprising a stable structure, a driving structure, a protection structure and a mounting structure;

the stabilizing structure comprises a first supporting plate (1), a vacuum insulation box (2), a first high-voltage wire (3), a second high-voltage wire (4), a fixed clamping plate (5), a movable clamping plate (6), a movable column (7), an adjusting plate (8), a reset spring (9), an eccentric wheel (10), a transmission shaft (11) and a driving shell (12), wherein the top of the first supporting plate (1) is fixedly connected with the vacuum insulation box (2), one side of the vacuum insulation box (2) is connected with the first high-voltage wire (3), the other side of the vacuum insulation box (2) is connected with the second high-voltage wire (4), the fixed clamping plate (5) is arranged below the first high-voltage wire (3) and the second high-voltage wire (4), the fixed clamping plate (5) is fixedly connected to the top of the first supporting plate (1), the movable clamping plate (6) is arranged above the first high-voltage wire (3) and the second high-voltage wire (4), the bottom of the movable clamping plate (6) is fixedly connected with a movable column (7), the bottom end of the movable column (7) is fixedly connected with an adjusting plate (8), the top of the adjusting plate (8) is fixedly connected with a plurality of reset springs (9), the reset springs (9) are fixedly connected to the bottom of the first supporting plate (1), the top of the adjusting plate (8) is provided with an eccentric wheel (10), one side of the eccentric wheel (10) is fixedly connected with a transmission shaft (11), and one end of the transmission shaft (11) is fixedly connected with a driving structure; the top surface of the fixed clamping plate (5) is provided with a plurality of uniformly distributed placing grooves, the bottom of the movable clamping plate (6) is fixedly connected with four movable columns (7) which are distributed in a rectangular structure, the first supporting plate (1) is provided with a plurality of movable holes, the bottom ends of the movable columns (7) penetrate through the movable holes and are fixedly connected to the top of the adjusting plate (8), a vacuum cavity is arranged inside the vacuum insulation box (2), connecting ports are arranged on two sides of the vacuum insulation box (2), one ends of the first high-voltage wire (3) and one ends of the second high-voltage wire (4) penetrate through the connecting ports and are arranged in the vacuum cavity, and insulating coatings are coated on the inner surface and the outer surface of the vacuum insulation box (2);

the driving structure comprises a driving shell (12), a double-shaft motor (13), a first chain wheel (14), a driving chain (15) and a second chain wheel (16), the driving shell (12) is fixedly connected to the bottom of a first supporting plate (1), the bottom of an inner cavity of the driving shell (12) is fixedly connected with the double-shaft motor (13), the first chain wheel (14) is fixedly connected to two output ends of the double-shaft motor (13), the side surface of the first chain wheel (14) is meshed with the driving chain (15), the driving chain (15) is meshed with the side surface of the second chain wheel (16), a transmission shaft (11) is fixedly connected to one side of the first chain wheel (14) and one side of the second chain wheel (16), two rotation holes which are symmetrically distributed are formed in the two side surfaces of the driving shell (12), and one end of the transmission shaft (11) penetrates through the rotation holes and is fixedly connected to one side of the transmission shaft (11);

the protective structure comprises a support column (17), a second support plate (18), a first sliding plate (19), a one-way threaded column (20), a sliding column (21), a second sliding plate (22), a first connecting column (23), a second connecting column (24) and a protective cover (25), wherein the support column (17) is fixedly connected to the bottom of the first support plate (1), the bottom end of the support column (17) is fixedly connected with the second support plate (18), the surface of the support column (17) is slidably connected with the first sliding plate (19), the first sliding plate (19) is in threaded connection with the surface of the one-way threaded column (20), one end of the one-way threaded column (20) is fixedly connected with a transmission component, the top of the first sliding plate (19) is fixedly connected with the sliding column (21), the top end of the sliding column (21) is fixedly connected with the second sliding plate (22), and one side of the second sliding plate (22) is fixedly connected with the first connecting column (23), one side adjacent to the second sliding plate (22) is fixedly connected with a second connecting column (24), the top of the second sliding plate (22) is fixedly connected with a buffering component, and the top of the buffering component is fixedly connected with a protective cover (25);

mounting structure is including fixed casing (35), reference column (36), reinforcing plate (37), mounting panel (38), two-way screw post (39), erection column (40) and anti-skidding grip block (41), fixed casing (35) rigid coupling in second backup pad (18) bottom, fixed casing (35) one side rigid coupling has reference column (36), reference column (36) one end rigid coupling has reinforcing plate (37), reinforcing plate (37) rigid coupling in second backup pad (18) bottom, reinforcing plate (37) surface sliding connection mounting panel (38), mounting panel (38) threaded connection is in two-way screw post (39) surface, two-way screw post (39) one end rigid coupling has power component, mounting panel (38) bottom rigid coupling erection column (40), anti-skidding grip block (41) of erection column (40) bottom rigid coupling.

2. Vacuum-type high-voltage insulation arrangement according to claim 1, characterized in that four support columns (17) are fastened to the top of the second support plate (18) in a rectangular configuration, the first sliding plate (19) is provided with four limiting holes distributed in a rectangular structure, the top end of the supporting column (17) penetrates through the limiting holes and is fixedly connected to the bottom of the first supporting plate (1), the top of the first sliding plate (19) is fixedly connected with four sliding columns (21) which are distributed in a rectangular structure, the first supporting plate (1) is provided with four sliding holes distributed in a rectangular structure, the top ends of the sliding columns (21) penetrate through the sliding holes and extend to the upper part of the first supporting plate (1), and the two ends of the first connecting column (23) and the two ends of the second connecting column (24) are fixedly connected with second sliding plates (22), and the four second sliding plates (22) are distributed in a rectangular structure.

3. Vacuum-type high-voltage insulation arrangement according to claim 1, characterized in that two symmetrically distributed stiffening plates (37) are fastened to the bottom of the second supporting plate (18), and one side of each of the two reinforcing plates (37) close to the fixed shell (35) is fixedly connected with two positioning columns (36) which are symmetrically distributed, the surface of the positioning column (36) is connected with two symmetrically distributed mounting plates (38) in a sliding way, the mounting plate (38) is provided with two positioning holes which are symmetrically distributed, one end of the positioning column (36) penetrates through the positioning holes and is fixedly connected with one side of the fixed shell (35), the mounting plate (38) is provided with a threaded hole, one end of the bidirectional threaded column (39) penetrates through the threaded hole and is rotatably connected to one side of the reinforcing plate (37), the bottom of the mounting plate (38) is fixedly connected with two symmetrically distributed mounting columns (40), and one side of the anti-skidding clamping plate (41) is fixedly connected with a plurality of anti-skidding strips.

4. Vacuum-type high voltage insulation arrangement according to claim 1,

the transmission assembly comprises a transmission shell (26), a rotating handle (27), a third chain wheel (28), a transmission chain (29) and a fourth chain wheel (30), the transmission shell (26) is fixedly connected to the bottom of the second support plate (18), the bottom surface of the transmission shell (26) is rotatably connected with the rotating handle (27), the top end of the rotating handle (27) is rotatably connected with the third chain wheel (28), the side surface of the third chain wheel (28) is meshed with the transmission chain (29), the transmission chain (29) is meshed with the side surface of the fourth chain wheel (30), the top surfaces of the third chain wheel (28) and the fourth chain wheel (30) are fixedly connected with one-way threaded columns (20), the second support plate (18) is provided with two symmetrically distributed mounting holes, the top ends of the one-way threaded columns (20) penetrate through the mounting holes and are rotatably connected to the bottom surface of the first support plate (1), the bottom surfaces of the third chain wheel (28) and the fourth chain wheel (30) are fixedly connected with the rotating handle (27), the bottom surface of the transmission shell (26) is provided with two preset holes which are symmetrically distributed, and the top end of the rotating handle (27) penetrates through the preset holes and extends to the inner cavity of the transmission shell (26);

the buffer assembly comprises a fixed column (31), a limiting plate (32), a buffer spring (33) and a buffer sleeve (34), wherein the fixed column (31) is fixedly connected to the top of the second sliding plate (22), the top end of the fixed column (31) is fixedly connected with the limiting plate (32), the top surface of the limiting plate (32) is fixedly connected with the buffer spring (33), the top end of the buffer spring (33) is fixedly connected to the inner wall of the top surface of the buffer sleeve (34), the buffer sleeve (34) is fixedly connected to the inner wall of the protective cover (25), the cross section of the protective cover (25) is of an arc-shaped structure, four buffer sleeves (34) distributed in a rectangular structure are fixedly connected to the inner wall of the protective cover (25), a buffer hole is formed in the bottom surface of the buffer sleeve (34), and the diameter of the buffer hole is larger than that of the fixed column (31) and smaller than the inner diameter of the buffer sleeve (34);

power component includes single-axis motor (42), main chain wheel (43), installation chain (44) and auxiliary chain wheel (45), single-axis motor (42) rigid coupling is in fixed casing (35) inner chamber lateral wall, output rigid coupling main chain wheel (43) of single-axis motor (42), main chain wheel (43) side meshing is connected installation chain (44), installation chain (44) meshing is connected in auxiliary chain wheel (45) side, just main chain wheel (43) and the equal rigid coupling in auxiliary chain wheel (45) one side have two-way screw post (39), the intercommunication mouth of two symmetric distributions is seted up to fixed casing (35) one side, two-way screw post (39) one end is run through the intercommunication mouth and is rotated and connect in reinforcing plate (37) one side.

5. The stable structure of the vacuum type high-voltage insulation device is characterized by comprising a first supporting plate (1), a vacuum insulation box (2), a first high-voltage wire (3), a second high-voltage wire (4), a fixed clamping plate (5), a movable clamping plate (6), a movable column (7), an adjusting plate (8), a reset spring (9), an eccentric wheel (10), a transmission shaft (11) and a driving shell (12), wherein the top of the first supporting plate (1) is fixedly connected with the vacuum insulation box (2), one side of the vacuum insulation box (2) is connected with the first high-voltage wire (3), the other side of the vacuum insulation box (2) is connected with the second high-voltage wire (4), the fixed clamping plate (5) is arranged below the first high-voltage wire (3) and the second high-voltage wire (4), the fixed clamping plate (5) is fixedly connected to the top of the first supporting plate (1), the movable clamping plate (6) is arranged above the first high-voltage wire (3) and the second high-voltage wire (4), the bottom of the movable clamping plate (6) is fixedly connected with a movable column (7), the bottom end of the movable column (7) is fixedly connected with an adjusting plate (8), the top of the adjusting plate (8) is fixedly connected with a plurality of reset springs (9), the reset springs (9) are fixedly connected to the bottom of the first supporting plate (1), the top of the adjusting plate (8) is provided with an eccentric wheel (10), one side of the eccentric wheel (10) is fixedly connected with a transmission shaft (11), and one end of the transmission shaft (11) is fixedly connected with a driving structure; fixed splint (5) top surface offer a plurality of evenly distributed's standing groove, it has four removal post (7) that are the rectangle structure and distribute to remove splint (6) bottom rigid coupling, a plurality of removal hole has been seted up in first backup pad (1), remove post (7) bottom and run through removal hole and rigid coupling in regulating plate (8) top, the inside vacuum chamber that is of vacuum insulation box (2), vacuum insulation box (2) both sides all are provided with connection port, first high-voltage line (3) and second high-voltage line (4) one end are equallyd divide and are do not penetrated and set up in the vacuum chamber from connection port, vacuum insulation box (2) internal surface and surface all coat have insulating coating.

6. The driving structure of the vacuum type high-voltage insulating device is characterized by comprising a driving shell (12), a double-shaft motor (13), a first chain wheel (14), a driving chain (15) and a second chain wheel (16), the driving shell (12) is fixedly connected with the bottom of the first supporting plate (1), the bottom of the inner cavity of the driving shell (12) is fixedly connected with a double-shaft motor (13), two output ends of the double-shaft motor (13) are fixedly connected with a first chain wheel (14), the side surface of the first chain wheel (14) is meshed and connected with a driving chain (15), the driving chain (15) is meshed and connected with the side surface of the second chain wheel (16), one side of the first chain wheel (14) and one side of the second chain wheel (16) are fixedly connected with a transmission shaft (11), two sides of the driving shell (12) are both provided with two symmetrically distributed rotating holes, one end of the transmission shaft (11) penetrates through the rotating hole and is fixedly connected to one side of the transmission shaft (11).

7. The protection structure of the vacuum type high-voltage insulation device is characterized by comprising a support column (17), a second support plate (18), a first sliding plate (19), a one-way threaded column (20), a sliding column (21), a second sliding plate (22), a first connecting column (23), a second connecting column (24) and a protective cover (25), wherein the support column (17) is fixedly connected to the bottom of the first support plate (1), the bottom end of the support column (17) is fixedly connected with the second support plate (18), the surface of the support column (17) is slidably connected with the first sliding plate (19), the first sliding plate (19) is in threaded connection with the surface of the one-way threaded column (20), one end of the one-way threaded column (20) is fixedly connected with a transmission component, the top of the first sliding plate (19) is fixedly connected with the sliding column (21), the top end of the sliding column (21) is fixedly connected with the second sliding plate (22), one side of the second sliding plate (22) is fixedly connected with the first connecting column (23), and one side of the second sliding plate (22) adjacent to the second connecting column (24) is fixedly connected, the top of the second sliding plate (22) is fixedly connected with a buffering component, and the top of the buffering component is fixedly connected with a protective cover (25).

8. A protective structure of a vacuum type high voltage insulation arrangement according to claim 7,

buffering subassembly includes fixed column (31), limiting plate (32), buffer spring (33) and buffering sleeve (34), fixed column (31) rigid coupling is at second sliding plate (22) top, fixed column (31) top rigid coupling limiting plate (32), limiting plate (32) top surface rigid coupling buffer spring (33), buffer spring (33) top rigid coupling is in buffering sleeve (34) top surface inner wall, buffering sleeve (34) rigid coupling is in protective cover (25) inner wall, the cross-section of protective cover (25) is the arc structure, just protective cover (25) inner wall rigid coupling has four buffering sleeve (34) that are the distribution of rectangle structure, buffering hole has been seted up to buffering sleeve (34) bottom surface, the diameter in buffering hole is greater than the diameter of fixed column (31) and is less than the internal diameter of buffering sleeve (34).

9. The mounting structure of the vacuum type high-voltage insulation device is characterized by comprising a fixed shell (35), a positioning column (36), a reinforcing plate (37), a mounting plate (38), a bidirectional threaded column (39), a mounting column (40) and an anti-skid clamping plate (41), the fixed shell (35) is fixedly connected with the bottom of the second supporting plate (18), one side of the fixed shell (35) is fixedly connected with a positioning column (36), one end of the positioning column (36) is fixedly connected with a reinforcing plate (37), the reinforcing plate (37) is fixedly connected with the bottom of the second supporting plate (18), the surface of the reinforcing plate (37) is slidably connected with a mounting plate (38), the mounting plate (38) is screwed on the surface of a bidirectional threaded column (39), two-way screw post (39) one end rigid coupling has power component, mounting panel (38) bottom rigid coupling erection column (40), mounting column (40) bottom rigid coupling antiskid grip block (41).

10. The vacuum type high-voltage insulation device mounting structure according to claim 9, wherein the power assembly comprises a single-shaft motor (42), a main chain wheel (43), a mounting chain (44) and an auxiliary chain wheel (45), the single-shaft motor (42) is fixedly connected to the inner cavity side wall of the fixed housing (35), the output end of the single-shaft motor (42) is fixedly connected to the main chain wheel (43), the main chain wheel (43) is engaged with the mounting chain (44), the mounting chain (44) is engaged with the auxiliary chain wheel (45) side, the main chain wheel (43) and the auxiliary chain wheel (45) are fixedly connected to one side by a two-way threaded column (39), two symmetrically distributed communication ports are formed in one side of the fixed housing (35), and one end of the two-way threaded column (39) is connected to one side of the reinforcing plate (37) in a penetrating mode through the communication ports in a rotating mode.