CN212757959U

CN212757959U - High-energy ion generator

Info

Publication number: CN212757959U
Application number: CN202020777523.8U
Authority: CN
Inventors: 王东君; 万发恒
Original assignee: Guizhou Quanshitong Precision Machinery Technology Co ltd
Current assignee: Guizhou Quanshitong Precision Machinery Technology Co ltd
Priority date: 2020-05-12
Filing date: 2020-05-12
Publication date: 2021-03-23
Anticipated expiration: 2030-05-12

Abstract

The utility model discloses a high-energy ion generator, wherein an excitation power supply is arranged inside a hollow pipe sleeve; an output electrode A, an output electrode B and an excitation end are fixedly arranged on the body of the excitation power supply, and the output electrode B penetrates through the pipe sleeve and is arranged outside the pipe sleeve; the inner electrode plate is arranged in the hollow part of the glass tube, the outer electrode net is sleeved outside the glass tube, and one end of the glass tube is detachably clamped with the tube sleeve; the output electrode B is elastically deformed and tightly pressed on the surface of the outer electrode net; the output electrode A and the excitation end are in close contact with the inner wall of the inner electrode slice; the outer electrode mesh is spaced from the tube sleeve. When the outer electrode net is discharged outside the glass tube to cause the glass tube to be damaged, the output electrode B is elastically deformed and buckled, the outer electrode net is separated from the glass tube, then the glass tube is separated and replaced from the tube sleeve, and the outer electrode net is tightly pressed on the outer side of the glass tube by the replaced output electrode B, so that the problems of resource waste and increased use cost of users caused by the integral replacement of the conventional high-energy ion generator are solved.

Description

High-energy ion generator

Technical Field

The utility model belongs to the air purification equipment field relates to a high energy ion generator.

Background

The high-energy ion tube generator is equipment for generating positive and negative ions and is widely applied to the fields of deodorization equipment and air purification; however, high-energy ionizers have been imported and modeled for a long time; the high-energy ion generator equipment is mostly used for deodorizing and purifying air in the industrial field, and is difficult to be combined with household air purification equipment to be applied to household air purification due to large size; the working principle of the high-energy ion generator is that the working principle of dielectric corona is utilized, namely, high voltage is discharged on the surface of the glass tube continuously, and the glass tube is broken after being used for a period of time due to frequent discharge on the surface of the glass tube; at present, the whole high-energy ion generator is directly replaced after the ion glass tube is broken, so that the whole is used as a consumable product, and the glass tube can not be replaced; because the main consumption piece is the glass tube, including glass tube, positive electrode, negative electrode and ion tube seat etc. when whole, cause the wasting of resources, increased user's use cost.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a high-energy ion generator.

The utility model discloses a following technical scheme can realize.

The utility model provides a pair of high energy ion generator, wherein, include: the excitation power supply is arranged inside the hollow pipe sleeve; an output electrode A, an output electrode B and an excitation end are fixedly arranged on the body of the excitation power supply, and the output electrode B penetrates through the pipe sleeve and is arranged outside the pipe sleeve;

the inner electrode plate is arranged in the hollow part of the glass tube, the outer electrode net is sleeved outside the glass tube, and one end of the glass tube is detachably clamped with the tube sleeve; the output electrode B is elastically deformed and tightly pressed on the surface of the outer electrode net; the output electrode A and the excitation end are in close contact with the inner wall of the inner electrode slice; the outer electrode net is spaced from the pipe sleeve;

the output electrode A and the excitation end are electrically connected with the positive conducting plate of the pipe sleeve; the output electrode B is electrically connected with the negative conducting strip of the pipe sleeve.

The body, the pipe sleeve and the glass pipe of the excitation power supply are all insulators.

The outer side end of the solid end of the glass tube far away from the tube sleeve is spherical, so that the outer electrode net can be conveniently installed in a guiding manner.

The pipe sleeve is fixedly connected with an extension end, a pressing part is fixed on the outer side of the extension end at intervals in the radial direction, a gap for clamping the glass pipe is formed between the inner surface of the pressing part and the outer surface of the extension end, and the glass pipe is clamped in the gap formed between the inner surface of the pressing part and the outer surface of the extension end in an interference manner; when the glass tube needs to be replaced, the glass tube is separated from the gap formed by the inner surface of the pressing part and the outer surface of the extending end.

The pressing part and the extending end are both insulators.

The pressing part is a plastic deformation body.

A plurality of needle point bodies are uniformly fixed on the inner surface of each outer electrode net from the cross point of each outer electrode net to the inner surface of the outer electrode net;

the tip of the needle point body faces to the circle center of the inner diameter of the outer electrode net; when the applied voltage reaches the discharge voltage of the gas, more energetic ions are generated in a short time under the point discharge of the needle point body.

The hollow inner surface of the tube seat is provided with a clamping groove; the outer end of the pipe sleeve is provided with a clamping protrusion matched with the pipe seat clamping groove; the positive and negative conducting strips of the tube seat are electrically connected with the positive and negative conducting strips of the tube sleeve.

And a limiting clamping table is fixed on the outer side of the tube seat.

The beneficial effects of the utility model reside in that: when the glass tube is damaged due to the fact that the external electrode net is placed on the outer side of the glass tube for a long time, the output electrode B is buckled in an elastic deformation mode, the external electrode net is separated from the glass tube, the glass tube is separated and replaced from the tube sleeve, the external electrode net is tightly pressed on the outer side of the glass tube through the replaced output electrode B, and the problems that resources are wasted and the use cost of a user is increased due to the fact that the existing high-energy ion generator is replaced integrally are solved.

Drawings

Fig. 1 is a schematic view of an explosive installation structure of the present invention;

fig. 2 is an external structural view of the present invention;

FIG. 3 is a schematic cross-sectional view taken along line C-C of FIG. 2;

fig. 4 is an external structure diagram of the external electrode mesh of the present invention.

In the figure: 1-tube seat; 2-pipe sleeve; 21-a pressing part; 22-an extension end; 3-excitation power supply; 31-output electrode B; 32-output electrode A; 33-an excitation end; 4-inner electrode slice; 5-a glass tube; 6-external electrode net; 61-needle point body.

Detailed Description

The technical solution of the present invention is further described below, but the scope of the claimed invention is not limited to the described.

See fig. 1-4.

The utility model discloses a high energy ion generator, wherein, include: the device comprises a pipe sleeve 2 and an excitation power supply 3, wherein the excitation power supply 3 is arranged inside the hollow pipe sleeve 2; an output electrode A32, an output electrode B31 and an excitation end 33 are fixedly arranged on the body of the excitation power supply 3, and an output electrode B31 penetrates through the pipe sleeve 2 and is externally arranged;

the electrode plate comprises an inner electrode plate 4, a glass tube 5 and an outer electrode net 6, wherein the inner electrode plate 4 is arranged in the hollow part of the glass tube 5, the outer electrode net 6 is sleeved outside the glass tube 5, and one end of the glass tube 5 is detachably clamped with the tube sleeve 2; the output electrode B31 is elastically deformed and pressed on the surface of the outer electrode net 6; the output electrode A32 and the excitation end 33 are closely contacted with the inner wall of the inner electrode plate 4; the outer electrode net 6 is spaced from the pipe sleeve 2;

the output electrode A32 and the excitation end 33 are electrically connected with the positive conducting strip of the pipe sleeve 2; the output electrode B31 is electrically connected with the negative conductive sheet of the pipe sleeve 2.

The working principle is as follows: the positive and negative conducting strips of the pipe sleeve 2 are connected with a power supply (DC12V), the output electrode A32 and the excitation end 33 enable the inner electrode sheet 4 to be electrified, the output electrode B31 enable the outer electrode net 6 to be electrified, a high-voltage electric field is formed between the inner electrode sheet 4 and the outer electrode net 6, when the external voltage reaches the discharge voltage of gas, the outer electrode net 6 discharges outside the glass tube 5, the gas is broken down to generate a mixture comprising electrons, ions, atoms and free radicals to form high-energy ion active groups, meanwhile, oxygen and moisture in the air near the outer electrode net 6 can also generate a large amount of nascent hydrogen, ozone, hydroxyl oxygen and other active groups under the action of the high-energy electrons, and harmful gas reacts with the active groups with higher energy to be finally converted into substances such as CO2, H2O and the like, so that the purpose of purifying the air is achieved;

when the outer electrode net 6 discharges outside the glass tube 5 for a long time to cause the glass tube 5 to be damaged, the output electrode B31 is buckled through elastic deformation, the outer electrode net 6 is separated from the glass tube 5, then the glass tube 5 is separated from the tube sleeve 2 for replacement, and the replaced output electrode B31 presses the outer electrode net 6 on the outside of the glass tube 5, so that the problems of resource waste and increased use cost of a user caused by the integral replacement of the conventional high-energy ion generator are solved.

The body of the excitation power supply 3, the pipe sleeve 2 and the glass pipe 5 are all insulators.

The outer end of the solid end of the glass tube 5, which is far away from the tube sleeve 2, is spherical, so that the outer electrode net 6 can be conveniently installed in a guiding way.

The pipe sleeve 2 is fixedly connected with an extension end 22, a pressing part 21 is fixed on the outer side of the extension end 22 at intervals in the radial direction, a gap for clamping the glass pipe 5 is formed between the inner surface of the pressing part 21 and the outer surface of the extension end 22, and the glass pipe 5 is clamped in the gap formed between the inner surface of the pressing part 21 and the outer surface of the extension end 22 in an interference manner; when the glass tube 5 needs to be replaced, the glass tube 5 is removed from the gap formed between the inner surface of the pressing portion 21 and the outer surface of the extending end 22.

The pressing portion 21 and the extending end 22 are insulators.

The pressing portion 21 is a plastically deformable body.

A plurality of needle point bodies 61 are uniformly fixed on the inner surface of the external electrode mesh 6 from the cross point of each mesh of the external electrode mesh 6;

the tip of the needle point body 61 faces the center of the inner diameter of the outer electrode net 6; when the applied voltage reaches the discharge voltage of the gas, more energetic ions are generated in a short time under the point discharge of the needle body 61.

The pipe support also comprises a pipe support 1, and a clamping groove is arranged on the hollow inner surface of the pipe support 1; the outer end of the pipe sleeve 2 is provided with a clamping protrusion matched with the clamping groove of the pipe seat 1; the positive and negative conductive sheets of the tube socket 1 are electrically connected with the positive and negative conductive sheets of the tube sleeve 2.

And a limiting clamping table is fixed on the outer side of the tube seat 1.

Claims

1. A high-energy ionizer, comprising: the device comprises a pipe sleeve (2) and an excitation power supply (3), wherein the excitation power supply (3) is arranged inside the hollow pipe sleeve (2); an output electrode A (32), an output electrode B (31) and an excitation end (33) are fixedly arranged on the body of the excitation power supply (3), and the output electrode B (31) penetrates through the pipe sleeve (2) to be externally arranged;

the electrode plate comprises an inner electrode plate (4), a glass tube (5) and an outer electrode net (6), wherein the inner electrode plate (4) is arranged in the hollow inner part of the glass tube (5), the outer electrode net (6) is sleeved on the outer side of the glass tube (5), and one end of the glass tube (5) is detachably clamped with the tube sleeve (2); the output electrode B (31) is elastically deformed and tightly pressed on the surface of the outer electrode net (6); the output electrode A (32) and the excitation end (33) are tightly contacted with the inner wall of the inner electrode slice (4); the outer electrode net (6) is spaced from the pipe sleeve (2);

the output electrode A (32) and the excitation end (33) are electrically connected with the positive conducting strip of the pipe sleeve (2); the output electrode B (31) is electrically connected with the negative conducting strip of the pipe sleeve (2).

2. The high-energy ionizer of claim 1 wherein: the body of the excitation power supply (3), the pipe sleeve (2) and the glass tube (5) are all insulators.

3. The high-energy ionizer of claim 1 wherein: the outer end of the solid end of the glass tube (5) far away from the tube sleeve (2) is spherical.

4. The high-energy ionizer of claim 1 wherein: the pipe sleeve (2) is fixedly connected with an extension end (22), a pressing part (21) is fixed on the outer side of the extension end (22) at intervals in the radial direction, and a gap for clamping the glass pipe (5) is formed between the inner surface of the pressing part (21) and the outer surface of the extension end (22).

5. The high-energy ionizer of claim 4 wherein: the pressing part (21) and the extending end (22) are both insulators.

6. The high-energy ionizer of claim 4 wherein: the pressing part (21) is a plastic deformation body.

7. The high-energy ionizer of claim 1 wherein: the cross-shaped cross points of each outer electrode net (6) are uniformly fixed with a plurality of needle point bodies (61) towards the inner surface of the outer electrode net (6).

8. The high-energy ionizer of claim 7 wherein: the pointed end of the needle point body (61) faces the center of the inner diameter of the outer electrode net (6).

9. The high-energy ionizer of claim 1 wherein: the pipe support is characterized by also comprising a pipe support (1), wherein the hollow inner surface of the pipe support (1) is provided with a clamping groove; the outer end of the pipe sleeve (2) is provided with a clamping protrusion matched with the clamping groove of the pipe seat (1); the positive and negative conducting strips of the tube seat (1) are electrically connected with the positive and negative conducting strips of the tube sleeve (2).

10. The high-energy ionizer of claim 9 wherein: and a limiting clamping table is fixed on the outer side of the tube seat (1).