CN113730637B - Device for activating nano material by high-frequency static electricity - Google Patents

Abstract

The invention discloses a device for activating nano materials by high-frequency static electricity, which comprises an upper connecting cover and a lower connecting shell, wherein a high-frequency static electricity activating device is arranged between the upper connecting cover and the lower connecting shell, the high-frequency static electricity activating device comprises an upper mounting shell and a lower mounting shell, static electricity brackets are arranged in the upper mounting shell and the lower mounting shell, a plurality of nano static tubes are arranged in the static electricity brackets, a static electricity discharging plate is arranged below the static electricity brackets, nano modules are arranged below the static electricity discharging plate, buffer positioning protection structures are arranged on two sides of the inner wall of the upper connecting cover, and shell connecting structures are arranged on two sides of the upper connecting cover and the lower connecting shell, and the device has the beneficial effects that: the device is convenient to install and fix, can be detached conveniently, adopts an electrostatic mode to perform excitation catalysis, has high oxidation potential, is a strong oxidation group, can oxidize most organic pollutants and partial inorganic pollutants, and has good effect.

Description

Device for activating nano material by high-frequency static electricity

Technical Field

The invention relates to the technical field of nano static electricity, in particular to a device for activating nano materials by adopting high-frequency static electricity.

Background

The nano material has strong oxidation-reduction capability under the action of visible light or ultraviolet light, has stable chemical property, can thoroughly decompose harmful organic matters such as formaldehyde, toluene, dimethylbenzene, ammonia, radon, TVOC and the like, pollutants, odor, bacteria, viruses, microorganisms and the like into harmless CO2 and H2O, has the characteristics of pollutant removal, hydrophilicity, self-cleaning property and the like, has lasting performance, does not generate secondary pollution, is a high-strength oxidation group, and can oxidize most organic pollutants and part of inorganic pollutants.

The general traditional catalysis principle technology of nano TiO2 is to excite and catalyze through ultraviolet light, and the ultraviolet light catalysis has the defects of short service life of ultraviolet light source and poor effect, and the existing device for killing influenza virus, coronavirus, escherichia coli and staphylococcus in air by utilizing the nano static technology has very simple structure, is integrally fixed in a fixed connection mode, is not easy to disassemble and maintain, and lacks the protection performance of the device.

For the problems in the related art, no effective solution has been proposed at present.

Disclosure of Invention

The present invention provides a device for activating nano materials by high frequency static electricity to overcome the above technical problems of the prior art.

The technical scheme of the invention is realized as follows:

the device for activating the nano material by adopting the high-frequency static electricity comprises an upper connecting cover and a lower connecting shell, wherein the high-frequency static electricity activating device is arranged between the upper connecting cover and the lower connecting shell; the high-frequency static activation device comprises an upper mounting shell and a lower mounting shell, openings are formed in the centers of the upper mounting shell and the lower mounting shell, positioning plates are arranged on the inner wall sides of the upper mounting shell and the lower mounting shell, static supports are arranged in the upper mounting shell and the lower mounting shell, a plurality of nano static tubes are arranged in the static supports, a static discharge plate is arranged below the static supports, nano modules are arranged below the static discharge plate, the nano modules are connected with the positioning plates on the lower mounting shell in a clamping mode, buffer positioning protection structures are arranged on two sides of the inner wall of an upper connecting cover, each buffer positioning protection structure comprises a first upper connecting plate and a first lower connecting plate, mounting nails connected with the upper connecting cover are symmetrically arranged on the first upper connecting plate, sliding grooves I are symmetrically arranged on the first upper connecting plate, sliding blocks I are movably arranged in the first lower sliding grooves, sliding blocks II are movably arranged in the sliding grooves, nano modules are arranged below the sliding blocks II, a movable shaft is arranged between the sliding blocks I and the sliding blocks, a buffer positioning rod is arranged on the first side plate II, a side plate is connected with the first connecting plate, a side plate is connected with one side of the first connecting plate, a side plate is provided with a side plate is connected with a first connecting plate, a side plate is provided with a second connecting plate, a side plate is connected with a side plate is provided with a buffer connecting plate, a side plate is connected with a side plate, a side plate is connected with a buffer plate, and a side plate is provided with a side plate is connected with a buffer connecting plate, and a side plate is provided with a side plate is connected with a buffer plate, and a side plate is connected with a buffer plate, the first mounting connecting block and the second mounting connecting block are mounted through mounting bolts, a through hole is formed in the first mounting connecting block in a penetrating mode, a cavity is formed in the first mounting connecting block, a downward pressing inserting connecting rod is arranged in the through hole in a penetrating mode, limiting pieces are arranged on two sides of a section of the downward pressing inserting connecting rod located in the cavity, a reset spring is sleeved below the limiting pieces and located in the cavity, a limiting block is arranged at the bottom end of the downward pressing inserting connecting rod, a positioning groove is formed in one side of the limiting block, a connecting hole communicated with the through hole is formed in the second mounting connecting block, an inserting hole communicated with a vertical angle of the connecting Kong Cheng is formed in one side of the second mounting connecting block, a transverse positioning rod is arranged in the inserting hole, and the transverse positioning rod is matched with the positioning groove; supporting legs are symmetrically arranged below the lower connecting shell, and supporting pads are symmetrically arranged below the supporting legs.

Still further, the static support includes second upper junction plate and second lower junction plate, the second upper junction plate with one side of second lower junction plate is equipped with and is connected with the connection curb plate, the second upper junction plate with all be equipped with on the second lower junction plate with nanometer electrostatic tube assorted static tube mounting hole.

Further, four elastic washers are arranged on the static discharge plate.

Furthermore, the upper mounting shell is provided with a connecting groove, and the lower mounting shell is provided with a connecting clamping block matched with the connecting groove.

Further, an upper notch is formed in the upper center of the upper connecting cover, and a lower notch is formed in the center of the lower portion of the lower connecting shell.

Still further, the inner walls of the upper connection cover and the lower connection case are provided with electrostatic blocking layers.

Still further, the first upper connecting plate and the first lower connecting plate are both provided with connecting sleeves, and an elastic connecting rod is connected between the connecting sleeves.

Further, inner support base plates are arranged on two sides of the inner wall of the lower connecting shell.

The invention provides a device for activating nano materials by high-frequency static electricity, which has the following beneficial effects:

(1) The high-frequency electrostatic activation device comprises an upper mounting shell and a lower mounting shell, openings are formed in the centers of the upper mounting shell and the lower mounting shell, positioning plates are arranged on the sides of the inner walls of the upper mounting shell and the lower mounting shell, an electrostatic support is arranged in the upper mounting shell and the lower mounting shell, a plurality of nano electrostatic tubes are arranged in the electrostatic support, an electrostatic discharge plate is arranged below the electrostatic discharge plate, nano modules are arranged below the electrostatic discharge plate, positioning plates on the nano modules and the lower mounting shell are clamped, buffer positioning protection structures are arranged on two sides of the inner wall of the upper mounting shell, shell connection structures are arranged on two sides of the upper mounting shell and the lower mounting shell, the device is convenient to mount and dismount, can play a good role in buffering during mounting and fixing, adopts an electrostatic mode to excite and catalyze, has a high oxidation potential, is a strong oxidation group, and can oxidize most organic pollutants and partial inorganic pollutants, and has a good effect.

(2) Supporting legs are symmetrically arranged below the lower connecting shell, supporting pads are symmetrically arranged below the supporting legs, and the lower connecting shell is supported.

(3) The static support comprises an upper connecting plate and a lower connecting plate, one side of the upper connecting plate and one side of the lower connecting plate are connected with connecting side plates, the upper connecting plate and the lower connecting plate are respectively provided with static tube mounting holes matched with the nano static tubes, the nano static tubes are conveniently mounted through the static tube mounting holes, and the stability after mounting can be improved due to the double-layer structure.

(4) Four elastic washers are arranged on the static discharge plate, and a certain protection effect is achieved on the static discharge plate after the static discharge plate is installed.

(5) The upper mounting shell is provided with a connecting groove, the lower mounting shell is provided with a connecting clamping block matched with the connecting groove, the clamping block is connected by utilizing the cooperation of the connecting groove, and the upper mounting shell and the lower mounting shell are convenient to limit.

(6) An upper notch is arranged at the center of the upper connecting cover, and a lower notch is arranged at the center of the lower part of the lower connecting shell, so that the nano material can be conveniently sterilized after being activated.

(7) The upper connecting cover and the inner wall of the lower connecting shell are respectively provided with an electrostatic blocking layer, and static electricity can be effectively prevented from being transferred to the outer walls of the upper connecting cover and the lower connecting shell by utilizing the action of the electrostatic blocking layers.

(8) The connecting sleeves are arranged on the upper connecting plate and the lower connecting plate, and elastic connecting rods are connected between the connecting sleeves, so that the auxiliary supporting and auxiliary buffering effects can be achieved by utilizing the action of the elastic connecting rods.

(9) And inner supporting base plates are arranged on two sides of the inner wall of the lower connecting shell and play a role in supporting the high-frequency electrostatic activating device from the bottom.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural view of a device for electrostatically activating nanomaterials using high frequency in accordance with an embodiment of the present invention;

fig. 2 is a schematic structural view of a device for electrostatically activating nanomaterials using high frequency in accordance with an embodiment of the present invention;

fig. 3 is a schematic structural view of a high-frequency electrostatic activation device in a device for activating nanomaterial using high-frequency electrostatic according to an embodiment of the present invention;

FIG. 4 is a schematic structural view of a buffer positioning protection structure in a device employing high frequency electrostatic activation of nanomaterials according to an embodiment of the present invention;

FIG. 5 is a schematic structural view of a housing connection structure in a device employing high frequency electrostatic activation of nanomaterials according to an embodiment of the present invention;

FIG. 6 is a schematic structural view of an electrostatic stent in a device employing high frequency electrostatic activation of nanomaterials according to an embodiment of the present invention;

fig. 7 is a schematic structural view of an electrostatic discharge plate in a device using high-frequency electrostatic activation nanomaterial according to an embodiment of the present invention;

fig. 8 is a schematic structural view of a nano-module in a device using high-frequency electrostatic activation of nano-materials according to an embodiment of the present invention.

In the figure:

1. an upper connection cover; 2. a lower connection housing; 3. a high-frequency electrostatic activation device; 4. an upper mounting shell; 5. a lower mounting case; 6. an opening; 7. a positioning plate; 8. an electrostatic support; 9. a nano electrostatic tube; 10. an electrostatic discharge plate; 11. a nano module; 12. a buffer positioning protection structure; 13. a first upper connection plate; 14. a first lower connection plate; 15. installing nails; 16. a first chute; 17. a first sliding block; 18. a second chute; 19. a second slide block; 20. a movable shaft; 21. a buffer positioning rod; 22. a rotating shaft; 23. a buffer spring; 24. connecting a first side plate; 25. a guide groove; 26. connecting a second side plate; 27. a guide block; 28. a housing connection structure; 29. installing a first connecting block; 30. installing a second connecting block; 31. installing a bolt; 32. a through hole; 33. a cavity; 34. pressing down the insertion rod; 35. a limiting piece; 36. a return spring; 37. a limiting block; 38. a positioning groove; 39. a connection hole; 40. a plug hole; 41. a transverse positioning rod; 42. support legs; 43. a support pad; 44. a second upper connecting plate; 45. a second lower connection plate; 46. connecting side plates; 47. an electrostatic tube mounting hole; 48. an elastic washer; 49. connecting a clamping block; 50. a connecting groove; 51. an upper notch; 52. a lower notch; 53. an electrostatic blocking layer; 54. connecting sleeves; 55. an elastic connecting rod; 56. an inner support pad.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which are derived by a person skilled in the art based on the embodiments of the invention, fall within the scope of protection of the invention.

The invention will be further described with reference to the accompanying drawings and detailed description below:

embodiment one:

referring to fig. 1-8, a device for activating nano materials by high frequency static electricity according to an embodiment of the present invention includes an upper connection cover 1 and a lower connection housing 2, a high frequency static electricity activation device 3 is installed between the upper connection cover 1 and the lower connection housing 2, the high frequency static electricity activation device 3 includes an upper installation housing 4 and a lower installation housing 5, an opening 6 is formed at the center of the upper installation housing 4 and the center of the lower installation housing 5, positioning plates 7 are respectively provided at the inner wall sides of the upper installation housing 4 and the lower installation housing 5, static electricity brackets 8 are installed in the upper installation housing 4 and the lower installation housing 5, a plurality of nano static electricity tubes 9 are installed in the static electricity brackets 8, a static electricity discharge plate 10 is installed below the static electricity discharge plate 10, a nano module 11 is installed below the static electricity discharge plate 10, the nano module 11 is clamped with the positioning plates 7 on the lower installation housing 5, the two sides of the inner wall of the upper connecting cover 1 are respectively provided with a buffer positioning protection structure 12, the buffer positioning protection structure 12 comprises a first upper connecting plate 13 and a first lower connecting plate 14, the first upper connecting plate 13 is symmetrically provided with mounting nails 15 connected with the upper connecting cover 1, the first upper connecting plate 13 is symmetrically provided with a first sliding chute 16, the first sliding chute 16 is internally and movably provided with a first sliding block 17, the first lower connecting plate 14 is symmetrically provided with a second sliding chute 18, the second sliding chute 18 is internally and movably provided with a second sliding block 19, a buffer positioning rod 21 is connected between the first sliding block 17 and the second sliding block 19 in a cross manner through a movable shaft 20, a rotating shaft 22 is movably arranged at the joint of the buffer positioning rod 21, buffer springs 23 are respectively connected between the buffer positioning rod 21 and the first upper connecting plate 13 and the first lower connecting plate 14, the utility model discloses a connecting device for the electric motor comprises a connecting plate, a connecting shell, a connecting plate and a connecting rod, wherein the two ends of the first upper connecting plate 13 are respectively provided with a connecting side plate 24, one side of the inner wall of the connecting side plate 24 is provided with a guide groove 25, the two ends of the first lower connecting plate 14 are respectively provided with a connecting side plate 26, one side of the outer wall of the connecting side plate 26 is provided with a guide block 27, the two sides of the upper connecting cover 1 and the lower connecting shell 2 are respectively provided with a shell connecting structure 28, the shell connecting structure 28 comprises a first mounting connecting block 29 and a second mounting connecting block 30, the first mounting connecting block 29 and the second mounting connecting block 30 are respectively installed through a mounting bolt 31, a through hole 32 is penetrated in the first mounting connecting block 29, a cavity 33 is formed in the first mounting connecting block 29, a lower inserting connecting rod 34 is arranged in the through hole 32, one side of the lower connecting rod 34 is provided with a limiting piece 35, the lower inserting connecting rod 34 is arranged on one side of the cavity 33, the lower inserting rod 34 is externally arranged on the lower connecting rod is sleeved with a reset spring 36, the reset spring 36 is arranged in the cavity 33, the lower connecting rod is arranged on the bottom of the lower connecting plate 35, the lower connecting rod 34 is provided with a limiting block 37, the lower connecting rod 37 is arranged on the bottom the connecting rod 30, the lower connecting rod is respectively provided with a transverse inserting connecting rod 39, one side of the connecting rod is communicated with a positioning hole 40, and a positioning hole 40 is arranged on one side 40, and is communicated with a transverse positioning hole 41.

Through the scheme of the invention, the high-frequency electrostatic activating device 3 is arranged between the upper connecting cover 1 and the lower connecting shell 2, the high-frequency electrostatic activating device 3 comprises an upper mounting shell 4 and a lower mounting shell 5, an opening 6 is arranged at the center of each of the upper mounting shell 4 and the lower mounting shell 5, positioning plates 7 are arranged on the side edges of the inner walls of the upper mounting shell 4 and the lower mounting shell 5, electrostatic brackets 8 are arranged in the upper mounting shell 4 and the lower mounting shell 5, a plurality of nano electrostatic tubes 9 are arranged in the electrostatic brackets 8, an electrostatic discharge plate 10 is arranged below the electrostatic brackets 8, a nano module 11 is arranged below the electrostatic discharge plate 10, the nano module 11 is clamped with the positioning plates 7 on the lower mounting shell 5, buffer positioning protection structures 12 are arranged on the two sides of the inner wall of the upper connecting cover 1, the buffer positioning protection structure 12 comprises a first upper connecting plate 13 and a first lower connecting plate 14, mounting nails 15 connected with the upper connecting cover 1 are symmetrically arranged on the first upper connecting plate 13, a first sliding groove 16 is symmetrically arranged on the first upper connecting plate 13, a first sliding block 17 is movably arranged in the first sliding groove 16, a second sliding groove 18 is symmetrically arranged on the first lower connecting plate 14, a second sliding block 19 is movably arranged in the second sliding groove 18, a buffer positioning rod 21 is connected between the first sliding block 17 and the second sliding block 19 in a cross manner through a movable shaft 20, a rotating shaft 22 is movably arranged at the joint of the buffer positioning rod 21, buffer springs 23 are respectively connected between the buffer positioning rod 21, the first upper connecting plate 13 and the first lower connecting plate 14, two ends of the first upper connecting plate 13 are respectively provided with a first connecting side plate 24, one side of the inner wall of the first connecting side plate 24 is provided with a guide groove 25, the two ends of the first lower connecting plate 14 are respectively provided with a second connecting plate 26, one side of the outer wall of the second connecting plate 26 is provided with a guide block 27, two sides of the upper connecting cover 1 and the lower connecting shell 2 are provided with a shell connecting structure 28, the shell connecting structure 28 comprises a first mounting connecting block 29 and a second mounting connecting block 30, the first mounting connecting block 29 and the second mounting connecting block 30 are all mounted through mounting bolts 31, a through hole 32 is arranged in the first mounting connecting block 29 in a penetrating way, a cavity 33 is arranged in the first mounting connecting block 29 in a penetrating way, a pressing inserting rod 34 is arranged in the through hole 32, two sides of one section of the pressing inserting rod 34 positioned in the cavity 33 are provided with limiting pieces 35, a reset spring 36 is sleeved below the limiting pieces 35 outside the pressing inserting rod 34, the reset spring 36 is positioned in the cavity 33, the bottom of the pushing-down plugging rod 34 is provided with a limiting block 37, one side of the limiting block 37 is provided with a positioning groove 38, the second mounting connection block 30 is internally provided with a connection hole 39 communicated with the through hole 32, one side of the second mounting connection block 30 is provided with a plugging hole 40 vertically connected with the connection hole 39, the plugging hole 40 is internally provided with a transverse positioning rod 41, the transverse positioning rod 41 is matched with the positioning groove 38, when the static electricity discharging device is used, firstly, the static electricity discharging plate 10 is arranged at the bottom of the static electricity discharging plate in a static electricity tube mounting hole 47 on the static electricity bracket 8, the nanometer module 11 is arranged below the static electricity discharging plate 10, finally, the whole body is arranged between the upper mounting shell 4 and the lower mounting shell 5 and is placed in the lower connection shell 2, the static electricity discharging plate 34 is pressed downwards by utilizing a shell connection structure 28, the limiting block 37 at the bottom end of the downward pressing plug rod 34 extends into the connecting hole 39 in the installation connecting block II 30, an upward force is generated by the action of the reset spring 36, the transverse positioning rod 41 penetrates through the plug hole 40 and extends into the positioning groove 38, the installation and fixation of the upper connecting cover 1 and the lower connecting shell 2 can be realized, meanwhile, when the installation is carried out, the buffer positioning protection structure 12 is utilized, the buffer positioning rod 21 is matched with the buffer spring 23, the sliding block I17 slides to two sides in the sliding groove I16, the sliding block II 19 slides to two sides in the sliding groove II 18, so that the first lower connecting plate 14 has a certain buffer protection effect when positioning the high-frequency electrostatic activation device 3, and finally, the static electricity releasing plate 10 is utilized to be matched with the nano static tube 9, so that the nano module 11 is activated, has a very high oxidation potential, the installation and fixation of the device are convenient, a very good buffer effect can be realized when the installation and fixation are carried out, the excitation catalysis is carried out in an electrostatic manner, the very high oxidation potential is provided, and the device is a strong oxidation group, and most of organic pollutants and partial inorganic pollutants can be oxidized.

Embodiment two:

as shown in fig. 6, a high-frequency electrostatic activation device 3 is installed between the upper connection cover 1 and the lower connection cover 2, the high-frequency electrostatic activation device 3 comprises an upper installation cover 4 and a lower installation cover 5, openings 6 are respectively formed in the centers of the upper installation cover 4 and the lower installation cover 5, positioning plates 7 are respectively arranged on the inner wall sides of the upper installation cover 4 and the lower installation cover 5, electrostatic brackets 8 are installed in the upper installation cover 4 and the lower installation cover 5, a plurality of nano electrostatic tubes 9 are installed in the electrostatic brackets 8, an electrostatic release plate 10 is installed below the electrostatic brackets 8, a nano module 11 is arranged below the electrostatic release plate 10, the nano module 11 is clamped with the positioning plates 7 on the lower installation cover 5, buffer positioning protection structures 12 are respectively arranged on the two sides of the inner wall of the upper connection cover 1, the buffer positioning protection structure 12 comprises a first upper connecting plate 13 and a first lower connecting plate 14, mounting nails 15 connected with the upper connecting cover 1 are symmetrically arranged on the first upper connecting plate 13, a first sliding groove 16 is symmetrically arranged on the first upper connecting plate 13, a first sliding block 17 is movably arranged in the first sliding groove 16, a second sliding groove 18 is symmetrically arranged on the first lower connecting plate 14, a second sliding block 19 is movably arranged in the second sliding groove 18, a buffer positioning rod 21 is connected between the first sliding block 17 and the second sliding block 19 in a cross manner through a movable shaft 20, a rotating shaft 22 is movably arranged at the joint of the buffer positioning rod 21, buffer springs 23 are respectively connected between the buffer positioning rod 21, the first upper connecting plate 13 and the first lower connecting plate 14, two ends of the first upper connecting plate 13 are respectively provided with a first connecting side plate 24, one side of the inner wall of the first connecting side plate 24 is provided with a guide groove 25, the two ends of the first lower connecting plate 14 are respectively provided with a second connecting plate 26, one side of the outer wall of the second connecting plate 26 is provided with a guide block 27, two sides of the upper connecting cover 1 and the lower connecting shell 2 are provided with a shell connecting structure 28, the shell connecting structure 28 comprises a first mounting connecting block 29 and a second mounting connecting block 30, the first mounting connecting block 29 and the second mounting connecting block 30 are all mounted through mounting bolts 31, a through hole 32 is arranged in the first mounting connecting block 29 in a penetrating way, a cavity 33 is arranged in the first mounting connecting block 29 in a penetrating way, a pressing inserting rod 34 is arranged in the through hole 32, two sides of one section of the pressing inserting rod 34 positioned in the cavity 33 are provided with limiting pieces 35, a reset spring 36 is sleeved below the limiting pieces 35 outside the pressing inserting rod 34, the reset spring 36 is positioned in the cavity 33, the bottom of the pushing-down plugging rod 34 is provided with a limiting block 37, one side of the limiting block 37 is provided with a positioning groove 38, the second mounting connection block 30 is internally provided with a connection hole 39 communicated with the through hole 32, one side of the second mounting connection block 30 is provided with a plugging hole 40 vertically communicated with the connection hole 39, the plugging hole 40 is internally provided with a transverse positioning rod 41, the transverse positioning rod 41 is matched with the positioning groove 38, the electrostatic bracket 8 comprises a second upper connection plate 44 and a second lower connection plate 45, one side of the second upper connection plate 44 and one side of the second lower connection plate 45 are respectively provided with a connection side plate 46, the second upper connection plate 44 and the second lower connection plate 45 are respectively provided with an electrostatic tube mounting hole 47 matched with the nano electrostatic tube 9, the nano electrostatic tube 9 is conveniently mounted by utilizing the electrostatic tube mounting hole 47, the stability after installation can be increased;

embodiment III:

as shown in fig. 3, a high-frequency electrostatic activation device 3 is installed between the upper connection cover 1 and the lower connection cover 2, the high-frequency electrostatic activation device 3 comprises an upper installation cover 4 and a lower installation cover 5, openings 6 are respectively formed in the centers of the upper installation cover 4 and the lower installation cover 5, positioning plates 7 are respectively arranged on the inner wall sides of the upper installation cover 4 and the lower installation cover 5, electrostatic brackets 8 are installed in the upper installation cover 4 and the lower installation cover 5, a plurality of nano electrostatic tubes 9 are installed in the electrostatic brackets 8, an electrostatic release plate 10 is installed below the electrostatic brackets 8, a nano module 11 is arranged below the electrostatic release plate 10, the nano module 11 is clamped with the positioning plates 7 on the lower installation cover 5, buffer positioning protection structures 12 are respectively arranged on the two sides of the inner wall of the upper connection cover 1, the buffer positioning protection structure 12 comprises a first upper connecting plate 13 and a first lower connecting plate 14, mounting nails 15 connected with the upper connecting cover 1 are symmetrically arranged on the first upper connecting plate 13, a first sliding groove 16 is symmetrically arranged on the first upper connecting plate 13, a first sliding block 17 is movably arranged in the first sliding groove 16, a second sliding groove 18 is symmetrically arranged on the first lower connecting plate 14, a second sliding block 19 is movably arranged in the second sliding groove 18, a buffer positioning rod 21 is connected between the first sliding block 17 and the second sliding block 19 in a cross manner through a movable shaft 20, a rotating shaft 22 is movably arranged at the joint of the buffer positioning rod 21, buffer springs 23 are respectively connected between the buffer positioning rod 21, the first upper connecting plate 13 and the first lower connecting plate 14, two ends of the first upper connecting plate 13 are respectively provided with a first connecting side plate 24, one side of the inner wall of the first connecting side plate 24 is provided with a guide groove 25, the two ends of the first lower connecting plate 14 are respectively provided with a second connecting plate 26, one side of the outer wall of the second connecting plate 26 is provided with a guide block 27, two sides of the upper connecting cover 1 and the lower connecting shell 2 are provided with a shell connecting structure 28, the shell connecting structure 28 comprises a first mounting connecting block 29 and a second mounting connecting block 30, the first mounting connecting block 29 and the second mounting connecting block 30 are respectively mounted through mounting bolts 31, a through hole 32 is arranged in the first mounting connecting block 29 in a penetrating manner, a cavity 33 is arranged in the first mounting connecting block 29, a lower push-fit connection rod 34 is arranged in the through hole 32 in a penetrating manner, two sides of one section of the lower push-fit connection rod 34 positioned in the cavity 33 are provided with limiting plates 35, a reset spring 36 is sleeved outside the lower part of the lower push-fit connection rod 34 and positioned in the cavity 33, the bottom end of the lower push-fit connection rod 34 is provided with a limiting block 37, one side of the limiting block 37 is provided with a positioning groove 38, a connecting hole 39 communicated with the through hole 32 is arranged in the second mounting connecting block 30, one side of the mounting connecting block 30 is provided with a vertical connecting block 40, the upper connecting block 4 is matched with the upper connecting shell 50, the upper connecting block 50 is matched with the positioning groove 50, and the upper connecting block 50 is matched with the upper connecting shell 50, and the lower connecting block 50 is matched with the connecting shell 50, and the connecting hole 50 is matched with the connecting hole 50, and the connecting hole 50;

embodiment four:

as shown in fig. 2, a high-frequency electrostatic activation device 3 is installed between the upper connection cover 1 and the lower connection cover 2, the high-frequency electrostatic activation device 3 comprises an upper installation cover 4 and a lower installation cover 5, openings 6 are respectively formed in the centers of the upper installation cover 4 and the lower installation cover 5, positioning plates 7 are respectively arranged on the inner wall sides of the upper installation cover 4 and the lower installation cover 5, electrostatic brackets 8 are installed in the upper installation cover 4 and the lower installation cover 5, a plurality of nano electrostatic tubes 9 are installed in the electrostatic brackets 8, an electrostatic release plate 10 is installed below the electrostatic brackets 8, a nano module 11 is arranged below the electrostatic release plate 10, the nano module 11 is clamped with the positioning plates 7 on the lower installation cover 5, buffer positioning protection structures 12 are respectively arranged on the two sides of the inner wall of the upper connection cover 1, the buffer positioning protection structure 12 comprises a first upper connecting plate 13 and a first lower connecting plate 14, mounting nails 15 connected with the upper connecting cover 1 are symmetrically arranged on the first upper connecting plate 13, a first sliding groove 16 is symmetrically arranged on the first upper connecting plate 13, a first sliding block 17 is movably arranged in the first sliding groove 16, a second sliding groove 18 is symmetrically arranged on the first lower connecting plate 14, a second sliding block 19 is movably arranged in the second sliding groove 18, a buffer positioning rod 21 is connected between the first sliding block 17 and the second sliding block 19 in a cross manner through a movable shaft 20, a rotating shaft 22 is movably arranged at the joint of the buffer positioning rod 21, buffer springs 23 are respectively connected between the buffer positioning rod 21, the first upper connecting plate 13 and the first lower connecting plate 14, two ends of the first upper connecting plate 13 are respectively provided with a first connecting side plate 24, one side of the inner wall of the first connecting side plate 24 is provided with a guide groove 25, the two ends of the first lower connecting plate 14 are respectively provided with a second connecting plate 26, one side of the outer wall of the second connecting plate 26 is provided with a guide block 27, two sides of the upper connecting cover 1 and the lower connecting shell 2 are provided with a shell connecting structure 28, the shell connecting structure 28 comprises a first mounting connecting block 29 and a second mounting connecting block 30, the first mounting connecting block 29 and the second mounting connecting block 30 are respectively mounted through a mounting bolt 31, a through hole 32 is arranged in the first mounting connecting block 29 in a penetrating way, a cavity 33 is arranged in the first mounting connecting block 29, a lower pressing plug rod 34 is arranged in the through hole 32 in a penetrating way, two sides of one section of the lower pressing plug rod 34, which is positioned in the cavity 33, are provided with limiting plates 35, a reset spring 36 is sleeved outside the lower part of the limiting plates 35, the reset spring 36 is positioned in the cavity 33, the bottom end of the lower pressing plug rod 34 is provided with a limiting block 37, one side of the limiting block 37 is provided with a positioning groove 38, a connecting hole 39 communicated with the through hole 32 is arranged in the second mounting connecting block 30, one side of the upper connecting block 30 is provided with a vertical plug rod 40, the upper connecting cover 1 is provided with a vertical plug rod 53, the lower connecting cover 41 is connected with an upper connecting layer 41, and the lower connecting cover 41 is connected with a lateral static electricity transferring hole 53, and the static electricity transferring hole is prevented from being connected with the upper connecting cover 1;

fifth embodiment:

as shown in fig. 4, a high-frequency electrostatic activation device 3 is installed between the upper connection cover 1 and the lower connection cover 2, the high-frequency electrostatic activation device 3 comprises an upper installation cover 4 and a lower installation cover 5, openings 6 are respectively formed in the centers of the upper installation cover 4 and the lower installation cover 5, positioning plates 7 are respectively arranged on the inner wall sides of the upper installation cover 4 and the lower installation cover 5, electrostatic brackets 8 are installed in the upper installation cover 4 and the lower installation cover 5, a plurality of nano electrostatic tubes 9 are installed in the electrostatic brackets 8, an electrostatic release plate 10 is installed below the electrostatic brackets 8, a nano module 11 is arranged below the electrostatic release plate 10, the nano module 11 is clamped with the positioning plates 7 on the lower installation cover 5, buffer positioning protection structures 12 are respectively arranged on the two sides of the inner wall of the upper connection cover 1, the buffer positioning protection structure 12 comprises a first upper connecting plate 13 and a first lower connecting plate 14, mounting nails 15 connected with the upper connecting cover 1 are symmetrically arranged on the first upper connecting plate 13, a first sliding groove 16 is symmetrically arranged on the first upper connecting plate 13, a first sliding block 17 is movably arranged in the first sliding groove 16, a second sliding groove 18 is symmetrically arranged on the first lower connecting plate 14, a second sliding block 19 is movably arranged in the second sliding groove 18, a buffer positioning rod 21 is connected between the first sliding block 17 and the second sliding block 19 in a cross manner through a movable shaft 20, a rotating shaft 22 is movably arranged at the joint of the buffer positioning rod 21, buffer springs 23 are respectively connected between the buffer positioning rod 21, the first upper connecting plate 13 and the first lower connecting plate 14, two ends of the first upper connecting plate 13 are respectively provided with a first connecting side plate 24, one side of the inner wall of the first connecting side plate 24 is provided with a guide groove 25, the two ends of the first lower connecting plate 14 are respectively provided with a second connecting plate 26, one side of the outer wall of the second connecting plate 26 is provided with a guide block 27, two sides of the upper connecting cover 1 and the lower connecting shell 2 are provided with a shell connecting structure 28, the shell connecting structure 28 comprises a first mounting connecting block 29 and a second mounting connecting block 30, the first mounting connecting block 29 and the second mounting connecting block 30 are all mounted through mounting bolts 31, a through hole 32 is arranged in the first mounting connecting block 29 in a penetrating way, a cavity 33 is arranged in the first mounting connecting block 29 in a penetrating way, a pressing inserting connecting rod 34 is arranged in the through hole 32 in a penetrating way, two sides of one section of the pressing inserting connecting rod 34 positioned in the cavity 33 are provided with limiting pieces 35, a reset spring 36 is sleeved outside the pressing inserting connecting rod 34 and positioned below the limiting pieces 35, the reset spring 36 is located in the cavity 33, a limiting block 37 is arranged at the bottom end of the pushing plug rod 34, a positioning groove 38 is formed in one side of the limiting block 37, a connecting hole 39 communicated with the through hole 32 is formed in the second mounting connecting block 30, a plug hole 40 communicated with the connecting hole 39 in a vertical angle is formed in one side of the second mounting connecting block 30, a transverse positioning rod 41 is arranged in the plug hole 40, the transverse positioning rod 41 is matched with the positioning groove 38, connecting sleeves 54 are arranged on the first upper connecting plate 13 and the first lower connecting plate 14, elastic connecting rods 55 are connected between the connecting sleeves 54, and the functions of auxiliary support and auxiliary buffering can be achieved by means of the action of the elastic connecting rods 55.

In order to facilitate understanding of the above technical solutions of the present invention, the following describes in detail the working principle or operation manner of the present invention in the actual process.

In practical application, when in use, firstly, the nano electrostatic tube 9 is arranged in the electrostatic tube mounting hole 47 on the electrostatic bracket 8, the electrostatic discharge plate 10 is arranged at the bottom of the electrostatic discharge plate, the nano module 11 is arranged below the electrostatic discharge plate 10, finally, the whole electrostatic discharge plate is arranged between the upper mounting shell 4 and the lower mounting shell 5 and is placed in the lower connecting shell 2, the shell connecting structure 28 is utilized to downwards press the push-down inserting rod 34, the limiting block 37 at the bottom end of the push-down inserting rod 34 extends into the connecting hole 39 in the second mounting connecting block 30, an upward force is generated by the action of the return spring 36, the transverse positioning rod 41 penetrates through the inserting hole 40 and extends into the positioning groove 38, so that the upper connecting cover 1 and the lower connecting shell 2 can be fixedly arranged, and meanwhile, the buffer positioning protection structure 12 is utilized, the buffer positioning rod 21 is matched with the buffer spring 23, the first slide block 17 slides to two sides in the first slide groove 16, the second slide block 19 slides to two sides in the second slide groove 18, so that the first lower connecting plate 14 has a certain buffer protection effect when positioning the high-frequency electrostatic activation device 3, and finally, the electrostatic release plate 10 is matched with the nano electrostatic tube 9, so that the nano module 11 is activated, has a very high oxidation potential, is convenient to install and fix, can be convenient to detach, can play a very good buffer effect when being installed and fixed, is excited and catalyzed in an electrostatic mode, has a very high oxidation potential, is a strong oxidation group, can oxidize most organic pollutants and partial inorganic pollutants, and has a good effect.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims (8)

1. The device for activating the nano material by adopting the high-frequency static electricity comprises an upper connecting cover (1) and a lower connecting shell (2), and is characterized in that a high-frequency static electricity activating device (3) is arranged between the upper connecting cover (1) and the lower connecting shell (2); the high-frequency electrostatic activation device (3) comprises an upper mounting shell (4) and a lower mounting shell (5), openings (6) are formed in the centers of the upper mounting shell (4) and the lower mounting shell (5), positioning plates (7) are arranged on the inner wall sides of the upper mounting shell (4) and the lower mounting shell (5), an electrostatic support (8) is arranged in the upper mounting shell (4) and the lower mounting shell (5), a plurality of nano electrostatic tubes (9) are arranged in the electrostatic support (8), an electrostatic release plate (10) is arranged below the electrostatic support (8), nano modules (11) are arranged below the electrostatic release plate (10), the nano modules (11) are clamped with the positioning plates (7) on the lower mounting shell (5), buffer positioning protection structures (12) are arranged on two sides of the inner wall of the upper connecting cover (1), each buffer positioning protection structure (12) comprises a first upper connecting plate (13) and a first lower connecting plate (14), a symmetrical upper connecting plate (16) is arranged on the first upper connecting plate (13) and is connected with the first connecting plate (16), the first lower connecting plate (14) is symmetrically provided with a second sliding chute (18), a second sliding block (19) is movably arranged in the second sliding chute (18), a buffer positioning rod (21) is connected between the first sliding block (17) and the second sliding block (19) in a cross manner through a movable shaft (20), a rotating shaft (22) is movably arranged at the joint of the buffer positioning rod (21), buffer springs (23) are connected between the buffer positioning rod (21) and the first upper connecting plate (13) and between the first lower connecting plate (14), two ends of the first upper connecting plate (13) are respectively provided with a first connecting side plate (24), the utility model discloses a connecting device, which is characterized in that a guiding groove (25) is arranged on one side of the inner wall of a first connecting plate (24), a second connecting plate (26) is arranged at two ends of a first lower connecting plate (14), a guiding block (27) is arranged on one side of the outer wall of the second connecting plate (26), a shell connecting structure (28) is arranged on two sides of an upper connecting cover (1) and a lower connecting shell (2), the shell connecting structure (28) comprises a first connecting block (29) and a second connecting block (30), the first connecting block (29) and the second connecting block (30) are all installed through a mounting bolt (31), a through hole (32) is formed in the first connecting block (29) in a penetrating manner, a cavity (33) is formed in the first installation connecting block (29), a downward pressing inserting connection rod (34) penetrates through the cavity (33) in the through hole (32), limiting plates (35) are arranged on two sides of one section of the downward pressing inserting connection rod (34) located in the cavity (33), a reset spring (36) is sleeved outside the downward pressing inserting connection rod (34) and located below the limiting plates (35), the reset spring (36) is located in the cavity (33), a limiting block (37) is arranged at the bottom end of the downward pressing inserting connection rod (34), a positioning groove (38) is formed in one side of the limiting block (37), a connecting hole (39) communicated with the through hole (32) is formed in the second installation connecting block (30), an inserting hole (40) communicated with the vertical connecting hole (39) in a bearing angle mode is formed in one side of the second installation connecting block (30), a transverse positioning rod (41) is arranged in the inserting hole (40), and the transverse positioning rod (41) is matched with the positioning groove (38); supporting legs (42) are symmetrically arranged below the lower connecting shell (2), and supporting pads (43) are symmetrically arranged below the supporting legs (42).

2. A device for activating nano-materials by high frequency static electricity according to claim 1, wherein the static electricity holder (8) comprises a second upper connecting plate (44) and a second lower connecting plate (45), one side of the second upper connecting plate (44) and one side of the second lower connecting plate (45) are provided with connecting side plates (46), and both the second upper connecting plate (44) and the second lower connecting plate (45) are provided with static tube mounting holes (47) matched with the nano-static tubes (9).

3. A device for activating nanomaterials using high frequency static electricity according to claim 1, wherein four elastic washers (48) are provided on the static electricity discharge plate (10).

4. The device for activating nano materials by high frequency static electricity according to claim 1, wherein the upper mounting shell (4) is provided with a connecting groove (50), and the lower mounting shell (5) is provided with a connecting clamping block (49) matched with the connecting groove (50).

5. The device for activating nano materials by high frequency static electricity according to claim 1, wherein an upper notch (51) is arranged at the upper center of the upper connecting cover (1), and a lower notch (52) is arranged at the lower center of the lower connecting shell (2).

6. A device for activating nanomaterials with high frequency static electricity according to claim 1, characterized in that the inner walls of the upper connection cover (1) and the lower connection housing (2) are provided with static electricity barrier layers (53).

7. A device for activating nanomaterials by high frequency static electricity according to claim 1, wherein the first upper connection plate (13) and the first lower connection plate (14) are provided with connection sleeves (54), and elastic connection rods (55) are connected between the connection sleeves (54).

8. A device for activating nanomaterials by high frequency static electricity according to claim 1, wherein the inner wall of the lower connection housing (2) is provided with inner support pads (56) on both sides.