CN220292232U

CN220292232U - Non-electrode heating type plasma source

Info

Publication number: CN220292232U
Application number: CN202322028438.8U
Authority: CN
Inventors: 缪同群; 谢圣鸣
Original assignee: Suzhou Linghui Photoelectric Technology Co ltd
Current assignee: Suzhou Linghui Photoelectric Technology Co ltd
Priority date: 2023-07-31
Filing date: 2023-07-31
Publication date: 2024-01-02
Anticipated expiration: 2033-07-31

Abstract

The utility model discloses a non-electrode heating type plasma source, which comprises a discharge chamber with an inlet and an outlet, an electron emission part, a magnetic part and a gas supply part, wherein the gas supply part is communicated with the inlet, the discharge chamber comprises a chamber wall, an upper electrode plate connected to the top of the chamber wall and forming the outlet, and a lower electrode plate connected to the bottom of the chamber wall and forming the inlet, and the chamber wall, the upper electrode plate and/or the lower electrode plate form a discharge current loop; the electron emission part is insulated from the discharge current loop, and comprises an electron emission part capable of emitting electrons by heating, and a heating part connected with the electron emission part, wherein the electron emission part is arranged in the discharge chamber and positioned on the flow path of the gas. According to the utility model, by arranging the independent discharge current loop, the large load of the discharge current on the heating element is avoided, so that the damage probability of the heating element is effectively reduced, the service life is prolonged, and the working safety of the ion source is improved.

Description

Non-electrode heating type plasma source

Technical Field

The utility model belongs to the technical field of ion sources, and particularly relates to a non-electrode heating type plasma source.

Background

The gas discharge, electron beam collisions with gas atoms (or molecules), the charged particle beam causes the working substance to sputter and the surface ionization process to generate ions and be extracted into a beam. Various types of ion sources have been developed depending on the conditions and uses. The more widely used arc discharge ion sources, PIG ion sources, dual plasma ion sources and dual Peng Yuan are all based on gas discharge processes.

Currently, a conventional plasma source includes a discharge chamber having an inlet and an outlet, an anode, a cathode, a magnetic member, and a gas supply member, wherein the magnetic member forms a magnetic field in the discharge chamber, the gas supply member is used to supply a working gas (argon) and a reaction gas (such as oxygen) into the discharge chamber, the anode is connected with a chamber wall of the discharge chamber, the cathode is a filament disposed in the discharge chamber, and when in operation, the filament generates hot electrons after being energized and heats, and moves and bombards atoms of the working gas or the reaction gas under the action of the magnetic field to ionize the atoms, and finally forms an ion beam to be ejected from the outlet of the discharge chamber under the guidance of the magnetic field.

However, in the actual working process, the discharge current of the ion source passes through the loop formed by the cathode and the anode, so that the heating electrode of the filament needs to bear excessive current, the heating electrode is easy to overheat and damage, the service life is low, and the potential safety hazard of the ion source in working is present.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art and provide an improved non-electrode heating type plasma source.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the non-electrode heating type plasma source comprises a discharge chamber with an inlet and an outlet, an electron emission part, a magnetic part and a gas supply part, wherein the gas supply part is communicated with the inlet, the discharge chamber comprises a chamber wall, an upper electrode plate connected to the top of the chamber wall and forming the outlet, and a lower electrode plate connected to the bottom of the chamber wall and forming the inlet, and the chamber wall and the upper electrode plate and/or the lower electrode plate form a discharge current loop; the electron emission part is insulated from the discharge current loop, and comprises an electron emission part capable of emitting electrons by heating, and a heating part connected with the electron emission part, wherein the electron emission part is arranged in the discharge chamber and positioned on the flow path of the gas.

According to a specific and preferred aspect of the present utility model, the air supply means comprises an air charging duct communicating with the inlet; the inner cavity of the discharge chamber is provided with a flow guide channel communicated with the inlet, wherein the flow guide channel extends from the inlet to the outlet, and the electron emission part is arranged in the flow guide channel. The flow of the gas is restrained through the diversion channel, so that the ionization effect generated by the electron bombardment of the gas atoms is effectively improved.

Preferably, the flow guide channel comprises an inner channel and an outer channel sleeved outside the inner channel, wherein the height of the outer channel is higher than that of the inner channel, the electron emission part is arranged in a hollow mode and is abutted against the space between the upper end of the inner channel and the upper end of the outer channel, a vent hole communicated with the upper end of the electron emission part and the upper end of the outer channel is formed, and gas flows out from the outlet after entering the inner cavity of the discharge chamber through the vent hole. The structure is simple and stable, and the assembly is convenient.

Preferably, the flow guide channel and the electron emission member are columnar, and the center lines of the inlet, the outlet, the flow guide channel and the electron emission member are overlapped.

Specifically, the aperture of the vent hole is d1, the inner diameter of the diversion channel is d2, wherein d1 is more than or equal to 0.15d2 and less than or equal to 0.25d2. Here, through setting up the air vent of aperture to reduce the velocity of flow of gaseous outflow water conservancy diversion passageway, thereby guarantee electron and gas atom and fully bump.

According to still another specific implementation and preferred aspect of the present utility model, the heating member includes a heat conduction module, a heating plate, and a heating power supply, wherein the heat conduction module is wrapped around the periphery of the flow guide channel, the heating plate is connected to the lower electrode plate in an insulating manner, one end portion of the heating plate is exposed and connected to the heating power supply, and the other end portion of the heating plate extends upwards into the inner cavity of the discharge chamber and is connected to the heat conduction module.

Preferably, the heat conduction module comprises a module body with a plugging channel formed in the middle part, and connecting parts connected to the module body and positioned on two opposite sides of the plugging channel, wherein the heating plates are respectively connected with the connecting parts on two sides, and the diversion channel is inserted in the plugging channel. Here, the module body both sides synchronous heating to promote heating efficiency, and ensure that the heat conduction is even.

Preferably, the heat conduction module and the diversion channel are made of graphite; and/or the electron emission member is any one of lanthanum hexaboride, tantalum and molybdenum. In some embodiments, the electron emitter employs lanthanum hexaboride (LAB 6), and continuous adjustment of the number of electrons emitted is achieved by adjusting the power of the heating, and adjusting the temperature of the LAB 6. The intensity of the final ions can be regulated within the maximum range, and the maximum working current which can be realized reaches 100A and above; and compared with the common filament, the lamp filament has long service life and does not need to be frequently disassembled and replaced.

According to a further specific and preferred aspect of the present utility model, an insulating ceramic is connected between the chamber wall and the upper electrode plate; a sealing ring is connected between the chamber wall and the lower electrode plate to form a current loop. Here, short circuit is prevented, and safety of the apparatus is improved.

In addition, the magnetic component adopts an electromagnet coil. The magnetic field generated is continuously adjustable to facilitate adjusting the ion source to an optimal operating condition.

Due to the implementation of the technical scheme, compared with the prior art, the utility model has the following advantages:

the existing ion source has the defects that a heating electrode is easy to overheat and damage and the service life is low, so that the potential safety hazard of the ion source in operation exists; the utility model skillfully solves various defects of the prior structure by carrying out integral design on the plasma source. After the plasma source is adopted, gas enters a current loop formed by discharging of the discharge chamber, wherein the current loop is formed by passing through the upper electrode plate, the lower electrode plate and the inner cavity of the discharge chamber, and the electron emission part is insulated from the current loop when being heated by the heating part.

Drawings

FIG. 1 is a schematic diagram of a non-electrode heating type plasma source according to the present embodiment;

FIG. 2 is a schematic exploded view of a non-electrode heating type plasma source according to the present embodiment;

FIG. 3 is a schematic front view of a non-electrode heating type plasma source according to the present embodiment;

FIG. 4 is a schematic cross-sectional view of A-A of FIG. 3;

wherein: 1. a discharge cell; 10. a chamber wall; t1, a diversion channel; t10, inner channel; t11, outer channel; 11. a lower electrode plate; k1, an inlet; h. a seal ring; 12. an upper electrode plate; k2, an outlet; c. insulating ceramics;

2. a gas supply part; 20. an inflation pipeline;

3. an electron emission member; 30. an electron emission member; k3, vent holes; 31. a heating member; 310. a heat conduction module; a1, a module body; t2, inserting a channel; a2, a connecting part; 311. and (5) heating the plate.

Detailed Description

The present utility model will be described in detail with reference to the drawings and the detailed description, so that the above objects, features and advantages of the present utility model can be more clearly understood. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model. The present utility model may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the utility model, whereby the utility model is not limited to the specific embodiments disclosed below.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "transverse", "length", "width", "thickness", "up", "down", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present utility model, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured" and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

In the utility model, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact through an intervening medium. Moreover, a first feature "above" and "over" a second feature may be a first feature directly above or obliquely above the second feature, or simply indicate that the first feature is higher in level than the second feature. The first feature being "under," "under" and "beneath" the second feature may be the first feature being directly under or obliquely under the second feature, or simply indicating that the first feature is less level than the second feature.

It will be understood that when an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "up," "down," "left," "right," and similar expressions are used herein for illustrative purposes only and are not meant to be the only embodiment.

As shown in fig. 1 to 4, the electrodeless heating type plasma source of the present embodiment includes a discharge chamber 1 having an inlet k1 and an outlet k2, a gas supply part 2, an electron emission part 3, and a magnetic part.

Specifically, the discharge chamber 1 includes a chamber wall 10, a lower electrode plate 11 connected to the bottom of the chamber wall 10 and forming an inlet k1, and an upper electrode plate 12 connected to the top of the chamber wall 10 and forming an outlet k2, wherein the chamber wall 10 and the upper electrode plate 12 are connected with insulating ceramics c to prevent a short circuit phenomenon; a sealing ring h is connected between the chamber wall 10 and the lower electrode plate 11 to form a current loop; the upper electrode plate 12 and the lower electrode plate 11 are both copper electrodes.

In this example, the air supply part 2 includes an air charging duct 20 communicating with the inlet k 1; in some embodiments, the inner cavity of the discharge chamber 1 is formed with a flow guiding channel t1 communicated with the inlet k1, wherein the flow guiding channel t1 extends from the inlet k1 to the outlet k2, and the gas flows upwards along the flow guiding channel t1 from the inlet k 1.

Specifically, the diversion channel t1 comprises an inner channel t10 and an outer channel t11 sleeved outside the inner channel t10, wherein the height of the outer channel t11 is higher than that of the inner channel t10, and the upper end part of the outer channel t11 is arranged at intervals with the outlet k 2.

In this example, the electron emission part 3 is provided in an insulated manner from the discharge current circuit, and the electron emission part 3 includes an electron emission member 30 capable of emitting electrons by heating, and a heating member 31 connected to the electron emission member 30, wherein the electron emission member 30 is provided in the discharge chamber 1 and is located on the flow path of the gas.

For convenience of implementation, the electron emission member 30 is disposed in the guide passage t 1. In some embodiments, the electron emission member 30 is disposed in a hollow manner and abuts against between the upper end of the inner channel t10 and the upper end of the outer channel t11, and the upper end of the electron emission member 30 and the upper end of the outer channel t11 form a vent hole k3 in communication, and the gas flows out from the outlet k2 after entering the inner cavity of the discharge chamber 1 through the vent hole k 3; the electron-emitting member 30 is made of lanthanum hexaboride.

Meanwhile, the flow guide channel t1 and the electron emission part 30 are columnar, and the central lines of the inlet k1, the outlet k2, the flow guide channel t1 and the electron emission part 30 are overlapped; the aperture of the vent hole k3 is d1, the inner diameter of the diversion channel t1 is d2, wherein d1 is more than or equal to 0.15d2 and less than or equal to 0.25d2, and the optimal d1=0.2d2.

In this example, the heating element 31 includes a heat conducting module 310, a heating plate 311, and a heating power supply, wherein the heat conducting module 310 is wrapped around the periphery of the flow guiding channel t1, the heating plate 311 is connected to the lower electrode plate 11 in an insulating manner, one end of the heating plate 311 is exposed and connected to the heating power supply, and the other end of the heating plate 311 extends upwards into the inner cavity of the discharge chamber 1 and is connected to the heat conducting module 310.

Specifically, the heat conduction module 310 includes a module body a1 with a plugging channel t2 formed in the middle, and connection portions a2 connected to the module body a1 and located at two opposite sides of the plugging channel t2, where the heating plates 311 are respectively connected to the connection portions a2 at two sides, and the flow guiding channel t1 is plugged in the plugging channel t 2; the heat conduction module 310 and the diversion channel t1 are made of graphite.

In addition, the magnetic component adopts an electromagnet coil; and the electromagnet coil may be disposed around the outer circumference of the discharge chamber 1, or may be disposed below or above the discharge chamber 1 to form a magnetic field capable of guiding the ion beam to be emitted.

In summary, after the plasma source is adopted, gas enters a current loop formed by discharging of a discharge chamber, wherein the current loop is formed by passing through an upper electrode plate, a lower electrode plate and an inner cavity of the discharge chamber, and an electron emission part is insulated from the current loop when being heated by a heating part, so compared with the prior art, the utility model has the advantages that on one hand, the independent current loop is arranged, and the large load of the discharge current to the heating part is avoided, thereby effectively reducing the damage probability of the heating part, prolonging the service life and improving the working safety of the ion source; the flow of the gas is restrained through the flow guide channel, and the flow velocity of the gas flowing out of the flow guide channel is reduced through the vent hole with a small aperture, so that the sufficient collision between electrons and gas atoms is ensured, and the ionization effect generated by the bombardment of the electrons on the gas atoms is effectively improved; the third electron emission member adopts lanthanum hexaboride (LAB 6), and the continuous adjustment of the quantity of emitted electrons is realized by adjusting the heating power and the temperature of the LAB 6. The intensity of the final ions can be regulated within the maximum range, the maximum working current can be 100A or more, and compared with the common filament, the filament has long service life and does not need to be frequently disassembled and replaced.

The present utility model has been described in detail with the purpose of enabling those skilled in the art to understand the contents of the present utility model and to implement the same, but not to limit the scope of the present utility model, and all equivalent changes or modifications made according to the spirit of the present utility model should be included in the scope of the present utility model.

Claims

1. A non-electrode heating type plasma source comprising a discharge chamber having an inlet and an outlet, an electron emission member, a magnetic member, and a gas supply member, wherein the gas supply member is in communication with the inlet, characterized in that: the discharge chamber comprises a chamber wall, an upper electrode plate connected to the top of the chamber wall and forming the outlet, and a lower electrode plate connected to the bottom of the chamber wall and forming the inlet, wherein the chamber wall and the upper electrode plate and/or the lower electrode plate form a discharge current loop; the electron emission part is arranged in an insulating way with the discharge current loop, and comprises an electron emission part capable of emitting electrons by heating and a heating part connected with the electron emission part, wherein the electron emission part is arranged in the discharge chamber and positioned on a gas flow path.

2. The non-electrode heating type plasma source according to claim 1, wherein: the air supply part comprises an air charging pipeline communicated with the inlet; the inner cavity of the discharge chamber is provided with a flow guide channel communicated with the inlet, wherein the flow guide channel extends from the inlet to the outlet, and the electron emission part is arranged in the flow guide channel.

3. The non-electrode heating type plasma source according to claim 2, wherein: the flow guide channel comprises an inner channel and an outer channel sleeved outside the inner channel, wherein the height of the outer channel is higher than that of the inner channel, the electron emission part is arranged in a hollow mode and props against the space between the upper end of the inner channel and the upper end of the outer channel, a vent hole which is communicated with the upper end of the electron emission part and the upper end of the outer channel is formed, and gas flows out of the outlet after entering the inner cavity of the discharge chamber through the vent hole.

4. The non-electrode heating type plasma source according to claim 3, wherein: the flow guide channel and the electron emission part are columnar, and the center lines of the inlet, the outlet, the flow guide channel and the electron emission part are overlapped.

5. The electrodeless heating type plasma source as claimed in claim 4, wherein: the aperture of the vent hole is d1, and the inner diameter of the diversion channel is d2, wherein d1 is more than or equal to 0.15d2 and less than or equal to 0.25d2.

6. The non-electrode heating type plasma source according to claim 2, wherein: the heating piece comprises a heat conduction module, a heating plate and a heating power supply, wherein the periphery of the flow guide channel is coated by the heat conduction module, the heating plate is connected to the lower electrode plate in an insulating mode, one end portion of the heating plate is exposed out of the heating power supply to be connected, and the other end portion of the heating plate extends into the inner cavity of the discharge chamber upwards and is connected with the heat conduction module.

7. The electrodeless heating type plasma source as claimed in claim 6, wherein: the heat conduction module comprises a module body, a connecting part and a heating plate, wherein the middle part of the module body forms an inserting channel, the connecting part is connected to the module body and positioned on two opposite sides of the inserting channel, the heating plate is respectively connected with the connecting parts on two sides, and the flow guide channel is inserted in the inserting channel.

8. The non-electrode heating type plasma source according to claim 6 or 7, wherein: the heat conduction module and the diversion channel are made of graphite; and/or the electron emission member is any one of lanthanum hexaboride, tantalum and molybdenum.

9. The non-electrode heating type plasma source according to claim 1, wherein: insulating ceramics are connected between the chamber wall and the upper electrode plate; and a sealing ring is connected between the chamber wall and the lower electrode plate and forms a current loop.

10. The non-electrode heating type plasma source according to claim 1, wherein: the magnetic component adopts an electromagnet coil.