KR102571324B1 - Filtered cathodic arc source device including trigger electrode - Google Patents

Abstract

an arc evaporation unit including a chamber; and a filter unit connected to the first end of the chamber, wherein the arc evaporation chamber is located at a second end opposite to the first end of the chamber, and the target a negative electrode to which members are bonded; an anode disposed spaced apart from the cathode and into which electrons emitted from the target member are introduced; and a triggering electrode for generating an arc in contact with the target member, wherein the triggering electrode is fixed to a point outside the anode based on the center of the chamber and can rotate around the point as an axis. , The anode includes a passage open to pass the triggering electrode, the triggering electrode may pass through the passage of the anode from outside the anode and contact the target member, and the triggering electrode includes a body; a fixing part located at one end of the body and fixed to a point outside the anode; and a contact portion located at the other end of the body and capable of contacting the target member. The magnetic field filtering arc source device provided in one aspect of the present invention has an effect of preventing melting of the trigger electrode by protecting the trigger electrode from high temperature and electron beam.

Description

Magnetic field filtration arc source device including trigger electrode {Filtered cathodic arc source device including trigger electrode}

The present invention relates to a magnetic field filtration arc source device including a triggering electrode.

In general, a vacuum arc deposition method, which is one of physical evaporation deposition methods among vacuum coating methods, is a method of forming a film by generating an arc discharge from a cathode target and evaporating a material of the target to deposit on a substrate. At this time, due to the evaporation of the target material, neutral particles, charged particles, and large particles are generated.

In order for this arc deposition method to be applied not only to simple cutting tools and general molds but also to the coating of precision molds and the development of semiconductor devices, macroparticles, which cause deterioration in the quality of films produced by the arc deposition method, Various methods are being sought for making a thin film deposition apparatus capable of preventing deposition on a substrate to be coated.

In the case of a serial thin film deposition apparatus, since the target and the substrate directly face each other, some of the large particles that are not ionized are deposited on the substrate, and thus the quality of the thin film is deteriorated. To solve this problem, the plasma duct is bent In addition, a thin film deposition apparatus using cathode arc discharge in which a magnetic field in the plasma duct is distributed along the plasma duct has been proposed.

For example, a rectangular thin film deposition apparatus has been proposed, but in this case, since a part of the magnetic force line at the curved part of the plasma duct is distributed crossing the plasma duct, charged particles (electrons, target ions, etc.) Since some of the plasma duct is guided to the inner wall of the bent portion of the plasma duct and collides with it, it disappears, resulting in a decrease in the deposition rate of the thin film.

Accordingly, the present inventor installs a reflective magnetic field source on the curved portion of the plasma duct, and pushes the magnetic force line at the curved portion to be distributed along the center line of the plasma duct, thereby guiding the movement of charged particles so that the charged particles do not collide with the inner wall of the plasma duct. An invention related to a thin film deposition apparatus using cathodic arc discharge has been registered as Korean Patent Registration No. 10-0230279.

A vacuum arc deposition apparatus including a general plasma duct includes an arc generating unit for generating an arc and a vacuum chamber unit to which the arc generated from the arc generating unit is supplied (FIG. 1).

The arc generating unit includes an arc evaporation unit including a carbon arc target, and a filter unit for filtering the arc generated from the arc evaporation unit.

In this case, the filter unit may be a magnetic field filtration filter, and since this is a self-evident matter in the field of arc discharge, a detailed description thereof will be omitted.

That is, the vacuum arc deposition apparatus including a general plasma duct makes the plasma, which is an electric charged particle among the evaporated matter generated from the arc evaporation unit, pass through well, while the macro-particle, which is an impurity, is filtered through the filter unit By doing so, it corresponds to a magnetic field filtration arc source capable of depositing a coating film containing no impurities in the vacuum chamber part.

Here, the triggering electrode can generate an arc by contacting the cathode. In the past, the triggering electrode is located too close to the cathode target emitting high-temperature heat, so the triggering electrode is melted by the high temperature and electron beam generated during arc discharge. There was a problem.

Accordingly, in order to solve these problems, a new type of triggering electrode structure has been required.

Korean Patent Publication No. 10-2013-0024361 A Korean Patent Publication No. 10-2016-0071085 A Korean Registered Patent No. 10-0230279 B1

An object of one aspect of the present invention is to provide a magnetic field filtration arc source device including a trigger electrode having a novel structure capable of preventing melting of the trigger electrode.

In order to achieve the above object, in one aspect of the present invention

an arc evaporation unit including a chamber; And a filter unit connected to the first end of the chamber; in the magnetic field filtration arc source device comprising a,

The chamber of the arc evaporation unit is

a cathode positioned at a second end opposite to the first end of the chamber and coupled to a target member;

an anode disposed spaced apart from the cathode and into which electrons emitted from the target member are introduced; and

A triggering electrode for generating an arc in contact with the target member; includes,

The trigger electrode may be fixed at a point outside the anode based on the center of the chamber and rotated about the point as an axis;

The anode includes an open passage through which the triggering electrode passes;

The triggering electrode may pass through the passage of the anode from the outside of the anode and contact the target member,

The triggering electrode is

body;

a fixing part located at one end of the body and fixed to a point outside the anode; and

a contact portion located at the other end of the body and capable of contacting the target member;

There is provided a magnetic field filtration arc source device comprising a.

The magnetic field filtration arc source device provided in one aspect of the present invention has an effect of preventing melting of the trigger electrode by protecting the trigger electrode from high temperatures and electron beams.

1 schematically shows the structure of a general magnetic field filtration arc source device,
2a and 2b schematically show the structure of an arc evaporation unit according to an embodiment of the present invention,
3 schematically shows the structure of an anode and a triggering electrode in an arc evaporation unit according to an embodiment of the present invention;
4 and 5 are schematic diagrams and images showing the effect of an electron beam on the structure of an anode and a triggering electrode in an arc evaporation unit according to an embodiment of the present invention;
6 schematically shows the structure of an anode and an anode cover according to an embodiment of the present invention,
7 schematically shows the side structure and passage of an anode according to an embodiment of the present invention;
8 schematically shows the arrangement of a conventional triggering electrode,
9 schematically shows the arrangement of a triggering electrode according to an embodiment of the present invention;
10 schematically shows the behavior of a triggering electrode according to an embodiment of the present invention;
11 schematically shows the structure of a triggering electrode according to an embodiment of the present invention;
12 is an image showing the structure and arrangement of a triggering electrode according to an embodiment of the present invention;
13 and 14 are images showing the effect on the triggering electrode according to an embodiment of the present invention according to the operation of the magnetic field filtration arc source device,
15 is a schematic diagram of an arc evaporation unit including a collecting unit and a shield unit according to an embodiment of the present invention;
16 is an image showing a collecting unit according to an embodiment of the present invention,
17 is a block diagram of a magnetic field filtration arc source device operating system according to an embodiment of the present invention;
18 is a flowchart of a method of operating a magnetic field filtration arc source device according to an embodiment of the present invention.

The present invention can apply various changes and thus various embodiments can come out, specific embodiments will be presented at the bottom and described in detail.

In addition, all terms in this specification that are not specifically defined will be able to be used in a meaning that can be understood by all those with ordinary knowledge in the technical field to which the present invention belongs.

However, it should be understood that the present invention is not limited to the specific embodiments described below, and includes all modifications, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Therefore, there may be other equivalents and modifications to the embodiments described in this specification, and the embodiments presented in this specification are only the most preferred embodiments.

In one aspect of the invention

an arc evaporation unit including a chamber; And a filter unit connected to the first end of the chamber; in the magnetic field filtration arc source device comprising a,

The chamber of the arc evaporation unit is

a cathode positioned at a second end opposite to the first end of the chamber and coupled to a target member;

an anode disposed spaced apart from the cathode and into which electrons emitted from the target member are introduced; and

A triggering electrode for generating an arc in contact with the target member; includes,

The trigger electrode may be fixed at a point outside the anode based on the center of the chamber and rotated about the point as an axis;

The anode includes an open passage through which the triggering electrode passes;

The triggering electrode may pass through the passage of the anode from the outside of the anode and contact the target member,

The triggering electrode is

body;

a fixing part located at one end of the body and fixed to a point outside the anode; and

a contact portion located at the other end of the body and capable of contacting the target member;

There is provided a magnetic field filtration arc source device comprising a.

Hereinafter, the magnetic field filtration arc source device provided in one aspect of the present invention will be described in detail for each configuration.

A magnetic field filtration arc source device provided in one aspect of the present invention includes an arc evaporation unit.

The arc evaporation unit includes a chamber.

In addition, the magnetic field filtration arc source device provided in one aspect of the present invention includes a filter unit.

The filter unit is connected to the first end of the chamber.

That is, hereinafter, a portion where the chamber is connected to the filter unit is referred to as a first end of the chamber, an opposite end thereof is referred to as a second end, and an outer circumferential surface between the first and second ends is referred to as a side surface.

The chamber may have a cylindrical shape in one embodiment, but is not limited thereto.

First, the chamber of the arc evaporation unit includes a cathode.

The cathode may be coupled to a target member.

The cathode may be located at the second end of the chamber.

In one embodiment, the cathode may be located in the center of the second end of the chamber.

In one embodiment, the target member may be carbon.

In another embodiment, the target member may be metal. For example, it may be one or more selected from the group consisting of titanium, chromium, aluminum, tungsten, and molybdenum.

The target member may have a columnar shape, for example, a cylindrical columnar or polygonal columnar shape, but is not limited thereto.

Next, the chamber of the arc evaporation unit includes an anode.

The anode may be disposed to be spaced apart from the cathode.

Electrons emitted from the target member may flow into the anode.

In one embodiment, the anode may be spaced apart from the cathode and may be disposed to extend along the side of the chamber.

The anode may include an open passage through which a triggering electrode to be described later may pass.

The anode may include carbon.

At this time, since the anode contains carbon, it has excellent heat resistance and can prevent the anode from being melted by the electron beam.

The passage of the anode may include a first part and a second part.

The second portion may be wider than the first portion (FIG. 7).

In the triggering electrode, a portion closer to a distance from a point to which the triggering electrode is fixed may pass through the first portion, and a portion farther away may pass through the second portion.

In one embodiment, when the anode is spaced apart from the cathode and is disposed to extend along the side surface of the chamber, the second part may be located closer to the first end of the chamber than the first part. .

If the width of the passage is narrow, target particles may accumulate and the moving path of the triggering electrode may be blocked, and if the width of the passage is wide, a welding part of the triggering electrode and the chamber may be melted by the electron beam generated from the arc. can Referring to FIGS. 4 and 5 , the effect of the electron beam can be confirmed.

Therefore, in one embodiment of the present invention, the width of the second part of the passage of the anode, where relatively large amount of target deposits are deposited, is designed by dividing the first part and the second part. Accordingly, while minimizing the arrival of electron beams to the triggering electrode and the welding portion of the chamber, it is possible to prevent the triggering electrode from being unable to move due to the passage being blocked by the target deposit.

At this time, the arc evaporation unit may further include an anode cover capable of being coupled and separated from one end of the anode.

In one embodiment, one end of the anode may be an end in the same direction as the first end of the chamber.

In one embodiment, the anode and the anode cover may be coupled and separated through rotation (FIG. 6).

In this case, the anode may include one or more protrusions at one end, and the anode cover may include one or more grooves corresponding to the protrusions of the anode.

Alternatively, the anode may include one or more grooves at one end, and the anode cover may include one or more protrusions corresponding to the grooves of the anode.

The anode cover can prevent melting of the welded portion of the chamber due to the electron beam generated from the arc.

Also, since the anode cover is coupled to the anode through rotation, it is possible to prevent the anode from being pushed even when deposits are accumulated.

Furthermore, since the anode cover can be separated from the anode through rotation, deposits can be easily removed after operation.

Next, the chamber of the arc evaporation unit includes a triggering electrode.

The triggering electrode may generate an arc by contacting the target member.

The triggering electrode may be fixed to a point outside the anode based on the center of the chamber and rotate about the point as an axis.

The triggering electrode may contact the target member by passing through the passage of the anode from the outside of the anode.

Conventionally, as can be seen in FIG. 8 , there is a problem in that the initiator electrode is easily melted because the initiator electrode is located too close to a cathode target emitting high-temperature heat.

Therefore, in the present invention, as shown in FIG. 9, the triggering electrode can be prevented from melting by being located outside the anode from the cathode target, and by rotating around a point outside the anode as an axis only when an arc is generated, the It can reach the target and generate an arc (FIG. 3, FIG. 10, FIG. 12).

The triggering electrode may include a body, a fixing portion positioned at one end of the body and fixed to a point outside the anode, and a contact portion positioned at the other end of the body and capable of contacting the target member. (FIG. 11).

The triggering electrode may further include a protection part surrounding an outer surface of the body.

The contact part and the protection part may include graphite.

As can be seen in FIGS. 13 and 14, when the magnetic field filtration arc source device is operated, a large amount of electron beam can reach the triggering electrode. Since the contact portion and the protection portion contain graphite, heat resistance is excellent, and the triggering electrode is It can be prevented from being melted by the electron beam.

The body may include a non-magnetic material, and may include, for example, at least one material selected from the group consisting of stainless steel, Inconel, and the like. As described above, since the protective portion surrounds the outer surface of the body, the body need not be limited to heat-resistant materials.

The triggering electrode generates an arc by contacting the target member, and after generating the arc, all parts of the triggering electrode may be located outside the anode with respect to the center of the chamber.

In addition, the chamber may further include a collection unit (FIG. 15).

The collecting unit may be disposed to surround the target member to collect sediment (FIG. 16).

The collecting unit may be arranged to collect sediments deposited in a gravitational direction from the target member, but is not limited thereto.

In one embodiment, when the target member is located at the second end of the chamber, the collecting part may also be located at the second end of the chamber to surround the target member.

It is preferable to use a material with excellent heat resistance and thermal shock resistance and excellent electrical insulation for the collecting part. For example, the collecting unit may include at least one ceramic material selected from the group consisting of Al ₂ O ₃ , BN, and SiC.

The collecting unit may have a cup-shaped structure with a concave center, and thus, by-products may be collected.

In addition, the chamber may further include a shield unit.

The shield part may be disposed such that one end contacts the collecting part, and an inner wall of the chamber may be blocked from an internal space of the chamber.

The shield unit may be disposed so that sediments deposited in the direction of gravity from the target member do not contact the inner wall of the chamber when moving in the direction of gravity, but is not limited thereto.

In one embodiment, when the target member is located at the second end of the chamber, and the collecting part is also located at the second end of the chamber so as to surround the target member, when viewed from the inside of the chamber, the shield unit is While in contact with the outer surface of the collecting portion, it may extend more outwardly (FIG. 15).

Any material capable of spatially blocking the inner wall of the chamber from the inner space of the chamber may be used as the shield part, but is preferably a material having heat resistance at a temperature of 300° C. or higher.

When the arc is operated for a long time, many by-products in addition to the drawn-out carbon plasma are coated on the surroundings, and these by-products may fall and destroy electrical insulation between the cathode and the surroundings.

Thus, through the collecting unit and the shield unit, even if the by-products are separated and accumulated, the insulation of the negative electrode can be maintained for a long time.

In another aspect of the invention

the magnetic field filtration arc source device; and

a control unit controlling triggering of the triggering electrode;

A magnetic field filtration arc source device operating system comprising a,

The control unit

a current measurement unit measuring a duct current generated by the arc evaporation unit;

a triggering induction unit that transmits a rotation signal to the triggering electrode so that the triggering electrode contacts the target member to regenerate an arc when the current measured by the current measuring unit is equal to or less than a predetermined value;

There is provided a magnetic field filtration arc source device operating system comprising a (see FIG. 17).

Hereinafter, the magnetic field filtration arc source device operating system provided in another aspect of the present invention will be described in detail for each configuration.

First, the magnetic field filtration arc source device operating system provided in one aspect of the present invention includes the magnetic field filtration arc source device.

Since the magnetic field filtration arc source device is the same as described above, it will not be repeatedly described.

Next, the magnetic field filtration arc source device operating system provided in another aspect of the present invention includes a control unit.

The control unit may include a current measuring unit.

When the plasma current generated by the arc evaporation unit enters the plasma duct, the duct current flows by the bias power applied to the duct, and the current sensor may measure the current.

Also, the control unit may include a trigger induction unit.

The trigger induction unit may transmit a rotation signal to the trigger electrode so that the trigger electrode contacts the target member to regenerate an arc when the current measured by the current measurer is less than or equal to a predetermined value.

If the motion of the arc spot is stably operated only on the surface of the target, only a certain amount of the target is always consumed for the same arc discharge current.

That is, since the position of the arc spot and the amount of current entering the duct of the magnetic field filtration arc source device have a specific relationship, the fact that the measured duct current value maintains a low current compared to the pre-calculated current value means that the location of the arc spot is desirable. means don't

Therefore, at this time, triggering can be induced so that the arc moves again from the center of the target. In this way, the current value of the carbon plasma beam entering the duct (filter) varies according to the movement of the arc spot in the target.

When the arc spot exists at the edge of the target, near the center, or at the outer wall of the target, the current value flowing through the duct is different, so it is possible that the current value of the duct stays below a predetermined value for a predetermined time or longer. At this time, the triggering electrode is operated to re-ignite the arc again.

In one embodiment, the triggering electrode is operated by a cylinder or a motor operated by pneumatic pressure. If the current entering the duct during the arc operation is reduced, that is, the current measured by the current measuring unit is reduced, it is received as a signal and triggered. Re-activating the electrode causes the arc to regenerate near the center of the target.

When the current entering the duct is small, the arc spot moves at the outer edge and edge of the target, while when the current is high, it means that the arc spot moves at the flat surface and center of the target. Therefore, if the current value measured by the current sensor is below a certain value, it means that the arc spot is moving outside, so the triggering electrode is re-operated to forcibly move the arc spot to the center of the target so that the arc starts again at the center of the target. make it happen

Through this, the arc spot can be kept only within a certain area of the cathode target, and the magnetic field filtration arc source device driving system provided in another aspect of the present invention finds the optimal magnetic field for the target and the target surface stays in a certain position. It is a system to ensure the efficiency of target use and the stability of the process.

In addition, the magnetic field filtration arc source device operating system provided in another aspect of the present invention may further include a supply unit.

The supply unit may supply the target member at a predetermined speed.

The supply unit may supply the target member at a constant speed.

The supply unit may be located on an outer surface of the target member when viewed from inside the chamber, and may push the target member toward the inside of the chamber.

The supply unit may include a motor capable of pushing the target member toward the inside of the chamber.

When the target is automatically supplied at a predetermined speed by the supply unit, a predetermined current value calculated using the supply speed of the target may be input to the control unit. Accordingly, there is an advantage that the target can be supplied more efficiently and stably.

In another aspect of the invention

As a magnetic field filtration arc source device operating method using the magnetic field filtration arc source device operating system,

generating an arc by contacting the triggering electrode with the target member;

measuring a duct current generated by the arc evaporation unit in real time by the current measuring unit;

transmitting, by the trigger induction unit, a rotation signal to the trigger electrode when the current measured by the current measurer is equal to or less than a predetermined value; and

regenerating an arc by rotating the triggering electrode according to a rotation signal of the triggering electrode and bringing the triggering electrode into contact with the target member;

There is provided a magnetic field filtration arc source device operating method comprising a.

Hereinafter, a magnetic field filtration arc source device operation method provided in another aspect of the present invention will be described in detail for each step, but the above-described magnetic field filtration arc source device and magnetic field filtration arc source device operating system can all be applied, , this will not be described redundantly.

First, a method of operating a magnetic field filtration arc source device provided in another aspect of the present invention includes generating an arc by contacting the triggering electrode with the target member.

After the triggering electrode generates an arc by contacting the target member, it is rotated again to be positioned outside the anode.

Prior to the step, the method of operating the magnetic field filtration arc source device provided in another aspect of the present invention may further include supplying the target member at a predetermined speed.

The target member may be supplied at a predetermined constant speed.

Next, a method of operating a magnetic field filtration arc source device provided in another aspect of the present invention includes measuring, in real time, a duct current generated by the arc evaporation unit in the current measuring unit.

Next, a method for operating a magnetic field filtration arc source device provided in another aspect of the present invention includes transmitting, by the triggering induction unit, a rotation signal to the triggering electrode when the current measured by the current measuring unit is equal to or less than a predetermined value. include

In one embodiment, a rotation signal may be transmitted when the current measured by the current measurement unit is maintained below a predetermined value for a predetermined time or longer.

Next, a method of operating a magnetic field filtration arc source device provided in another aspect of the present invention includes the step of regenerating an arc by rotating the triggering electrode according to a rotation signal of the triggering electrode and contacting the triggering electrode with the target member. can include

Accordingly, the arc spot can stably stay on the surface of the target, and the source can be operated for a long time because the target can be properly supplied by the consumed amount by keeping the consumption of the target constant.

10 Cathode
20 anode
21 anode cover
22 aisle
22a first part
22b second part
30 trigger electrode
31 body
32 fixed part
33 contact
34 protection
40 collection unit
50 shield part
100 chamber
110 First end of chamber
Second end of 120 chamber
200 filter unit
1000 magnetic field filtration arc source device
2000 supply department
3000 controller
3100 current measuring unit
3200 Trigger Induction Unit
10000 magnetic field filtration arc source device driving system

Claims (5)

an arc evaporation unit including a chamber; And a filter unit connected to the first end of the chamber; in the magnetic field filtration arc source device comprising a,
The chamber of the arc evaporation unit is
a cathode positioned at a second end opposite to the first end of the chamber and coupled to a target member;
an anode disposed spaced apart from the cathode and into which electrons emitted from the target member are introduced; and
A triggering electrode for generating an arc in contact with the target member; includes,
The triggering electrode may be fixed to a point outside the anode based on the center of the chamber and rotate about the point as an axis;
The anode includes an open passage through which the triggering electrode passes;
The triggering electrode may pass through the passage of the anode from the outside of the anode and contact the target member,
The triggering electrode is
body;
a fixing part located at one end of the body and fixed to a point outside the anode;
a contact portion located at the other end of the body and capable of contacting the target member; and
Including; a protection unit surrounding the outer surface of the body,
The magnetic field filtration arc source device, characterized in that the contact portion and the protection portion include graphite.
delete delete According to claim 1,
The magnetic field filtration arc source device, characterized in that the body comprises a non-magnetic material.
According to claim 1,
The triggering electrode generates an arc by contacting the target member,
After generating the arc, all parts of the trigger electrode are located outside the anode based on the center of the chamber.