阅读说明：本技术 一种多点导电离子管 (Multipoint conductive ion tube ) 是由 陈玉明 于 2021-08-26 设计创作，主要内容包括：本发明公开了一种多点导电离子管,属于离子管技术领域,旨在提供一种离子发生量强且运输时不易损坏的多点导电离子管,包括管体、导电棒和内网电极,导电棒和内网电极置于管体内,管体由FR-4复合玻璃纤维环氧材质构成,内网电极包括不锈钢电极和紫铜导电带,不锈钢电极与紫铜导电带连接,紫铜导电带与导电棒连接。(The invention discloses a multipoint conductive ion tube, which belongs to the technical field of ion tubes and aims to provide a multipoint conductive ion tube with strong ion generation amount and difficult damage during transportation.)

1. A multipoint conductive ion tube comprises a tube body, a conductive rod and an inner mesh electrode, wherein the conductive rod and the inner mesh electrode are arranged in the tube body,

the pipe body is made of FR-4 composite glass fiber epoxy material,

the internal mesh electrode comprises a stainless steel electrode and a red copper conductive belt, the stainless steel electrode is connected with the red copper conductive belt,

the red copper conductive belt is connected with the conductive rod.

2. The multipoint conductive ion tube of claim 1, wherein: the stainless steel electrode is a circular tube rolled by a stainless steel plate, one end of the stainless steel plate is bent into the circular tube to form a connecting plate, and the red copper conductive belt is arranged on the connecting plate and welded with the stainless steel electrode.

3. The multipoint conducting ion tube of claim 2, wherein: the red copper conductive belt and the stainless steel electrode are in multipoint spot welding.

4. The multipoint conductive ion tube of claim 3, wherein: the stainless steel electrode is made of hard elastic 304 stainless steel.

5. The multipoint conducting ion tube according to any of claims 1-4, wherein: the outer electrode is formed by a stainless steel net sleeve, the outer electrode is formed by a sleeve body and an adjusting body which are integrally connected, the section of the sleeve body is C-shaped, and the section of the adjusting body is V-shaped.

6. The multipoint conductive ion tube of claim 5, wherein: and the conductive rod is provided with a plurality of layers of conductive contact pieces which are butted with the inner grid electrode.

7. The multipoint conductive ion tube of claim 6, wherein: the multipoint conductive ion tube comprises a plastic cover for sealing the tube body, and the conductive rod and the plastic cover are connected through screws.

8. The multipoint conductive ion tube of claim 7, wherein: and the joint of the plastic cover and the pipe body is poured and sealed by liquid epoxy resin.

Technical Field

The invention relates to the technical field of ion tubes, in particular to a multipoint conductive ion tube.

Background

The ion tube is a common article for industrial deodorization, and the aluminum alloy inner electrode adopted by the high-energy ion tube is widely applied due to good electric conductivity.

However, the aluminum alloy electrode has a defect of being easily oxidized into white powdery alumina after being used for a long time, thereby affecting the service life and the effect of the product;

the glass tube corona medium is made of a material, so that the glass tube corona medium is easy to break in transportation and use, is easy to harden and break when meeting water, and has unsatisfactory ion generation amount;

the conventional stainless steel inner electrode has larger resistance, and an ion tube using the stainless steel inner electrode has larger resistance and needs higher voltage and current, so that the safety and the creepage resistance of the ion tube are much poorer.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a multipoint conductive ion tube which is strong in ion generation amount and not easy to damage during transportation.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a multiple spot conductive ion tube, includes body, conducting rod and interior mesh electrode, and the conducting rod is arranged in the body with interior mesh electrode, and the body is FR-4 composite glass fiber epoxy pipe, and interior mesh electrode includes stainless steel electrode and red copper conductive band, and the stainless steel electrode is connected with red copper conductive band, and red copper conductive band is connected with the conducting rod.

Furthermore, the stainless steel electrode is formed by rolling a stainless steel plate into a circular tube, one end of the stainless steel plate is bent into the circular tube to form a connecting plate, and the red copper conductive belt is arranged on the connecting plate and is welded with the stainless steel electrode.

Further, the red copper conductive belt and the stainless steel electrode are subjected to multipoint spot welding.

Further, the stainless steel electrode is made of hard elastic 304 stainless steel.

Furthermore, an outer electrode is sleeved outside the tube body and is formed by a stainless steel net sleeve, the outer electrode is formed by a sleeve body and an adjusting body which are integrally connected, the cross section of the sleeve body is C-shaped, and the cross section of the adjusting body is V-shaped.

Furthermore, a plurality of layers of conductive contact pieces which are abutted against the inner grid electrode are arranged on the conductive rod.

Furthermore, the multipoint conductive ion tube comprises a plastic cover for sealing the tube body, and the conductive rod and the plastic cover are connected through screws.

Further, the joint of the plastic cover and the pipe body is sealed by pouring liquid epoxy resin.

Furthermore, the silver conductive band replaces a red copper conductive band, so that the resistance can be greatly reduced.

By adopting the technical scheme, the invention has the beneficial effects that:

1. the tube body is made of composite material FR-4 non-glass material and is used as a corona medium layer, and the FR-4 material is formed by polymerizing glass fiber and epoxy resin, so that the ion generation amount is increased by times;

2. hardened stainless steel is used as an inner grid electrode, a red copper conductive belt is used as a multipoint conductive electrode, and a conductive rod consisting of an aluminum alloy solid upright post is used as a support; the stainless steel inner mesh electrode is relatively tightly attached to a tube body made of FR-4 composite glass epoxy materials due to good elasticity;

3. the stainless steel has larger resistance, so the ion generation amount of corona is poorer than that of aluminum alloy, and the red copper conductive belt is used for conducting electricity, so the defect of overlarge conductive resistance of the stainless steel is overcome by a multipoint distribution conductive method, and the ion generation amount is further increased by times;

4. the tube body formed by FR-4 is used, so that the ion tube is not easy to break during transportation, and the service life is greatly prolonged.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural view of the tube and the outer electrode;

FIG. 3 is a schematic view of the connection structure of the inner mesh electrode and the red copper conductive band;

reference numerals: the device comprises a tube body 1, an outer electrode 11, a sleeve body 11a, an adjusting body 11b, a conductive rod 2, a conductive contact piece 21, an inner mesh electrode 3, a stainless steel electrode 31, a red copper conductive belt 32, a connecting plate 31a, a welding point 301 and a plastic cover 4.

Detailed Description

Embodiments of the present invention are further described with reference to fig. 1 to 3.

A multipoint conductive ion tube with strong ion generation amount and difficult damage in transportation is provided.

Specific embodiments of the invention:

the utility model provides a multiple spot conductive ion tube, includes body 1, conducting rod 2 and interior mesh electrode 3, and in body 1 was arranged in to conducting rod 2 and interior mesh electrode 3, body 1 was FR-4 composite glass fiber epoxy pipe, and interior mesh electrode 3 includes stainless steel electrode 31 and red copper conductive band 32, and stainless steel electrode 31 is connected with red copper conductive band 32, and red copper conductive band 32 is connected with conducting rod 2.

The pipe body 1 is made of FR-4 composite glass fiber epoxy resin, so that the ion generation amount is increased by times; and the formed ion tube is not easy to break in transportation, and the service life is greatly prolonged.

The stainless steel electrode 31 is a circular tube rolled by a stainless steel plate, one end of the stainless steel plate is bent into the circular tube to form a connecting plate 31a, the red copper conductive belt 32 is arranged on the connecting plate 31a and welded with the stainless steel electrode 31, the red copper conductive belt 32 is connected with the stainless steel electrode 31 by multipoint spot welding, and the stainless steel electrode 31 is made of hard elastic 304 stainless steel.

The red copper conductive and stainless steel electrode 31 is connected with the stainless steel electrode 31 through multi-point electric welding, and a multi-point distribution conductive method solves the defect of overlarge conductive resistance of stainless steel, realizes stronger ion generation amount under the condition of smaller voltage and current, and greatly improves the safety and the anti-creeping property of the ion tube; the stainless steel mesh electrode 3 has good elasticity and is tightly adhered to the tube body 1 made of FR-4 material.

An outer electrode 11 is sleeved outside the tube body 1, the outer electrode 11 is formed by a stainless steel mesh sleeve, the outer electrode 11 is formed by a sleeve body 11a and an adjusting body 11b which are integrally connected, the section of the sleeve body 11a is C-shaped, and the section of the adjusting body 11b is V-shaped.

The outer electrode 11 is sleeved on the tube body 1, the adjusting body 11b is pinched to change the angle of the outer electrode 11b, so that the diameter of the outer electrode 11 is adjusted, the outer electrode 11 is connected with the tube body 1 more closely, and the outer electrode 11 is not easy to loosen on the tube body 1.

The conducting rod 2 is provided with a plurality of layers of conducting contact pieces 21 which are abutted against the inner mesh electrode 3, the conducting contact pieces 21 are provided with at least two layers, each layer is provided with at least two conducting contact pieces 21, and the conducting contact pieces 21 are made of aluminum alloy.

The conductive contact pieces 21 on the layers increase the contact area with the stainless steel inner mesh electrode 3, and reduce the resistance, so that the conductivity is more stable, and the service life of the ion tube is prolonged.

The multipoint conductive ion tube comprises a plastic cover 4 for sealing the tube body 1, a conductive rod 2 and the plastic cover 4 are connected through a screw, and the joint of the plastic cover 4 and the tube body 1 is sealed through pouring of liquid epoxy resin.

The sealing effect between the plastic cover 4 and the tube body 1 is better, foreign matters such as water and dust are not easy to enter the ion tube, and the service life of the ion tube is prolonged.

Case comparison:

the comparison of the invention and the ion tube of the imported mainstream brand under the same temperature, humidity and wind speed is as follows: (temperature 35 degree humidity 95% wind speed 6 m/s)

Voltage (Voltage V)	1700	2000	2300	2600	2900
						Amount of ion generation (cubic centimeter)	1000-1500	5000-6000	9000-10200	17 ten thousand to 19 ten thousand	26 ten thousand to 29 ten thousand

TABLE 1 (invention)

Voltage (Voltage V)	1700	2000	2300	2600	2900
						Amount of ion generation (cubic centimeter)	600-700	2000-2500	4000-5000	11 ten thousand to 12 ten thousand	13-15 million

TABLE 2 (American ATMOSAIR corporation ionic tube inlet)

In table 2, the inner mesh electrode of the ion tube is made of stainless steel and is filled in the glass tube in a coil form and connected with a conductive rod.

The comparison of the two groups of data in the table 1 and the table 2 shows that the ion generation amount of the ion tube is far more than the values of other ion tubes; tables 1 and 2 are only one group of data, and under other same-temperature humidity wind speeds, the ion generation amount of the invention is far more than the values of other ion tubes;

the invention adopts a tube body formed by FR-4 composite glass fiber epoxy, and assists the red copper conductive band to be welded with the stainless steel inner net electrode in a multi-spot welding manner, so that the numerical value of the formed multi-spot conductive ion tube on the ion generation amount is far more than that of the ion tube formed by the glass tube on the market.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and those skilled in the art should be able to make general changes and substitutions within the technical scope of the present invention.