KR102544225B1 - Reactor with twisted rotation axis and powder ALD apparatus including the same - Google Patents

Abstract

The present invention relates to a reactor having a twisted axis of rotation so as to deposit a thin film on powder with a uniform thickness in an atomic layer deposition (ALD) process, and a powder ALD device including the same. A reactor for a powder ALD apparatus according to the present invention includes a reaction tube, a first cover and a second cover. The reaction tube has a first opening and a second opening so as to communicate with each other. The first cover covers the first opening, and an injection shaft for injecting gas is formed to protrude outside the first opening, and the injection shaft is used as a rotation shaft during rotation. The second cover covers the second opening, and a connecting shaft connected to the drive shaft of the motor is formed to protrude outward from the second opening, and the connecting shaft is twisted with respect to the injection shaft.

Description

Reactor with twisted rotation axis and powder ALD apparatus including the same}

The present invention relates to a powder atomic layer deposition (ALD) apparatus, and more particularly, to a reactor having a twisted axis of rotation so as to deposit a thin film on powder with a uniform thickness in an ALD process, and a powder ALD apparatus including the reactor. it's about

In order to coat a specific material on the surface of the powder, an atomic layer deposition (ALD) method may be used. This ALD method is also referred to as a powder ALD (P-ALD) method.

Among powder ALD devices, a rotary type has a structure in which a tubular reactor rotated by a motor is disposed inside a tubular heat source. The powder ALD process is performed by introducing a metal precursor gas or the like into the reactor after inserting powder, which is a material to be coated, into the reactor. As the particle surfaces of the powder are exposed to the metal precursor gas, the metal precursor gas is deposited on the particle surfaces.

As shown in FIG. 1, the reactor 2 for a powder ALD device has a cylindrical tube shape and is configured to rotate in a horizontal direction. The reactor 2 has an inner circumferential surface 3 having the same inner diameter, and a plurality of stirring blades 9 capable of uniformly stirring the powder are formed on the inner circumferential surface 3. The inner circumferential surface 3 of the rotating reactor 2 is formed horizontally to the rotation shaft. In the ALD process, after supplying powder into the reactor 2, gas is injected into the first opening 5 on one side of the reactor 2 while rotating the reactor 2 in an axial direction horizontal to the ground It can proceed in the form of being discharged to the second opening 7 on the other side. 1 is a cross-sectional view showing a conventional reactor 2 for a powder ALD device having a constant inner diameter. IN represents a direction in which gas is injected, and OUT represents a direction in which gas is discharged. R represents the direction of rotation of the reactor 2, and S represents the direction in which the powder is stirred.

Since such a conventional reactor 2 is arranged in a horizontal direction and the inner circumferential surface 3 has a constant inner diameter, when there is no gas injected into the reactor 2, the powder is not stirred up and down rather than generally. It is made in a local form such as movement (S). Due to this, a difference in thickness may occur depending on the position of the inside of the reactor 2 when the powder is deposited as a thin film. That is, a problem in that the thin film is not uniformly deposited on the powder may occur.

And, when gas is injected into one side of the reactor 2 and discharged to the other side of the reactor 2, the movement of the powder may occur in the direction in which the gas moves. As a result, as shown in FIGS. 2 to 4, the powder gathers toward the second opening 7 of the reactor 2 through which the gas is discharged, causing a problem that the filter installed on the second opening 7 is clogged. can Here, FIG. 2 is a photograph of the reactor 2 of FIG. 1, showing the second opening 7 of the reactor before the ALD process. FIG. 3 is a photograph showing the second opening 7 of the reactor 2 after the ALD process of FIG. 2 . And FIG. 4 is a photograph showing filters respectively installed in the first opening and the second opening of the reactor 2 of FIG. 2 .

That is, comparing FIGS. 2 and 3 , it can be confirmed that the powder is collected in the second opening 7 of the reactor after the ALD process. As a result, it can be confirmed that more powder is deposited on the filter installed in the second opening of the reactor shown in FIG. 4(b) than on the filter installed in the first opening of the reactor shown in FIG. can

Registered Patent No. 10-2086574 (2020.03.09. Notice)

Accordingly, an object of the present invention is to provide a reactor having a twisted axis of rotation and a powder ALD device including the reactor so that a thin film can be deposited on powder with a uniform thickness in an ALD process.

Another object of the present invention is to provide a reactor with a twisted axis of rotation and a powder ALD device including the same, which allows the powder to be uniformly distributed in the reactor so that the powder is generally stirred in the reactor.

Another object of the present invention is a reactor with a twisted axis of rotation capable of suppressing the problem that a filter installed on the side of the second opening is clogged with powder by moving the powder in the direction of gas movement toward the second opening, which is an outlet, and a powder ALD including the same to provide the device.

In order to achieve the above object, the present invention is a reaction tube formed with a first opening and a second opening in communication; a first cover that covers the first opening, has an injection shaft for injecting gas protrudes outward from the first opening, and the injection shaft is used as a rotation shaft during rotation; and a second cover covering the second opening and having a connecting shaft connected to the driving shaft of the motor protrude outward from the second opening, and the connecting shaft being twisted with respect to the injection shaft. A reactor for an ALD device is provided.

The injection shaft and the connecting shaft are horizontal axes, respectively, and may be formed parallel to each other at the center of the first and second covers.

The reaction tube may be inclined at a predetermined angle and interposed between the first and second covers.

The reaction tube is horizontally interposed between the first and second covers, and the injection shaft is formed in the first cover to be eccentric with respect to the central axis of the reaction tube.

The injection shaft may be located on the same axis as the drive shaft of the motor.

The reactor for a powder ALD device according to the present invention may further include a link shaft that connects the driving shaft of the motor and the connection shaft located on the same shaft as the injection shaft.

A reactor for a powder ALD device according to the present invention includes a first filter interposed between the first opening and the first cover; and a second filter interposed between the second opening and the second cover.

The present invention also provides a heat source for supplying heat; The reactor rotatably installed inside the heat source and receiving heat from the heat source to perform atomic layer deposition (ALD) on the surface of the powder provided therein; and a motor connected to the reactor via a driving shaft to rotate the reactor.

According to the present invention, since the reactor rotates with the axis of rotation twisted, the powder can be uniformly distributed in the reactor so that the powder can be stirred throughout the reactor. That is, since the reactor rotates in a conical shape or eccentrically by a twisted rotational shaft, it is possible to achieve overall stirring of the powder in the reactor.

Since the powder is generally stirred in the reactor, a thin film can be deposited on the powder with a uniform thickness.

In addition, by uniformly distributing the powder in the reactor, it is possible to suppress a problem in which the powder is moved toward the second opening in the direction of movement of the gas and the filter installed at the second opening is clogged with the powder.

1 is a cross-sectional view showing a conventional reactor for a powder ALD device having a constant inner diameter.
FIG. 2 is a photograph of the reactor of FIG. 1, showing an outlet of the reactor before an ALD process.
FIG. 3 is a photograph showing the outlet of the reactor after the ALD process of FIG. 2 .
FIG. 4 is a photograph showing filters respectively installed at the inlet and outlet of the reactor of FIG. 2 .
5 is a view showing a powder ALD device including a reactor having a twisted rotation axis according to a first embodiment of the present invention.
Figure 6 is a view showing the rotation of the reactor of Figure 5;
7 is a view showing a powder ALD device including a reactor having a twisted rotation axis according to a second embodiment of the present invention.
Figure 8 is a view showing the rotation of the reactor of Figure 7;

It should be noted that in the following description, only parts necessary for understanding the embodiments of the present invention are described, and descriptions of other parts will be omitted without departing from the gist of the present invention.

The terms or words used in this specification and claims described below should not be construed as being limited to ordinary or dictionary meanings, and the inventors have appropriately used the concept of terms to describe their inventions in the best way. It should be interpreted as a meaning and concept consistent with the technical spirit of the present invention based on the principle that it can be defined in the following way. Therefore, the embodiments described in this specification and the configurations shown in the drawings are only preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, so various equivalents that can replace them at the time of the present application. It should be understood that there may be variations and variations.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

[First Embodiment]

5 is a view showing a powder ALD device including a reactor having a twisted rotation axis according to a first embodiment of the present invention. And Figure 6 is a view showing the rotation of the reactor of Figure 5.

Referring to FIGS. 5 and 6 , the powder ALD device 100 according to the first embodiment includes a heat source 10 for supplying heat, and ALD is applied to the surface of the powder provided therein by receiving heat from the heat source 10. It includes a reactor 20 to perform and a motor 50 connected to the reactor 20 via a driving shaft 51 to rotate the reactor 20 . Here, the reactor 20 includes a reaction tube 21, a first cover 35 and a second cover 41. The reaction tube 21 has a first opening 25 and a second opening 27 formed in communication with each other. The first cover 35 covers the first opening 25, and an injection shaft 37 for injecting gas is formed to protrude outward from the first opening 25, and when rotated, the injection shaft 37 It is used as the axis of rotation. And the second cover 41 covers the second opening 27, and the connection shaft 43 connected to the driving shaft 51 of the motor 50 is formed to protrude outward from the second opening 27. and the connecting shaft 27 is twisted with respect to the injection shaft 37.

In this way, since the injection shaft 37 and the connecting shaft 43 of the reactor 20 according to the first embodiment are twisted, the reactor 20 rotates and stirs the powder inside up, down, left and right by itself (S) can be performed.

The powder ALD device 100 according to the first embodiment may further include a link shaft 45 and a chamber 80 .

As described above, the reactor 20 includes the reaction tube 21, the first cover 35 and the second cover 41, the first filter 31, the second filter 33 and the link shaft 45 ) may be further included.

The reaction tube 21 has a cylindrical tube shape with first and second openings 25 and 27 formed on both sides. Although not shown, the reaction tube 21 may include a plurality of stirring blades formed on an inner circumferential surface so as to stir the powder injected therein while rotating, as shown in FIG. 2 . A plurality of stirring blades may be formed to protrude toward the center of the inner circumferential surface of the reaction tube 21 .

The reaction tube 21 is installed inclined at a certain angle with respect to the horizontal axis of rotation. The inclination of the reaction tube 21 may be appropriately set in consideration of conditions in which the powder can be uniformly stirred in the reaction tube 21 .

The first and second openings 25 and 27 of the reaction tube 21 are sealed by first and second covers 35 and 41, respectively.

The first cover 35 is coupled to the first opening 25 via the first filter 31 . An injection shaft 37 having an injection port 39 communicating with the inside of the reaction tube 21 is formed on the first lid 35 . A gas required for the ALD process is injected into the reaction tube 21 through the inlet 39 . The injection shaft 37 is supported so that the reaction tube 21 can rotate. That is, the injection shaft 37 is used as a rotation shaft when the reaction tube 21 rotates.

The second cover 41 is coupled to the second opening 27 via the second filter 33 . A connecting shaft 43 is formed at the center of the second cover 41 . The connecting shaft 43 is connected to the drive shaft 51 of the motor 50 that rotates the reactor 20 .

The motor 50 provides a driving force necessary for rotation of the reaction tube 21 through the drive shaft 51 . The drive shaft 51 is coaxial with the injection shaft 37 . Because of this, since the drive shaft 51 and the connection shaft 43 are shifted from each other, the drive shaft 51 and the connection shaft 43 are connected via the link shaft 45.

And the chamber 80 contains the heat source 10 and the reactor 20 . The chamber 80 makes the reactor 20 in a vacuum state during the ALD process.

The reactor 20 according to the first embodiment is rotated and the injection shaft 37 and the connection shaft 43 are parallel to each other as horizontal axes so that the powder can be stirred (S) in up, down, left and right inside by itself. It is formed at the center of the first and second covers 35 and 41. That is, since the reaction tube 21 is installed inclined at a certain angle with respect to the horizontal axis of rotation, the injection shaft 37 and the connection shaft 43 are not located coaxially but are offset from each other.

Since the connection shaft 43 is twisted with respect to the injection shaft 37 used as the rotation shaft in this way, the connection shaft 43 and the driving shaft 51 are coupled via the link shaft 45. Here, the link shaft 45 connects the driving shaft 51 and the connecting shaft 43 of the motor 50 positioned on the same axis as the injection shaft 37 .

Due to this, the driving shaft 51 of the motor 50 and the injection shaft 37 are located on the same axis in the horizontal direction.

In this way, in the reactor 20 according to the first embodiment, the reaction tube 21 is installed inclined at a certain angle with respect to a horizontal axis of rotation formed by the drive shaft 51 and the injection shaft 37. Therefore, when the motor 50 is driven, the reaction tube 21 moves up and down while rotating. That is, the reaction tube 21 rotates in a conical shape as a whole.

Specifically, it can be assumed that gas is injected into the rotating reactor 20 through the first opening 25 and discharged through the second opening 27 in a state in which powder is supplied to the inside of the reactor 20. When the powder is stirred, the powder is basically stirred up and down by the stirring blades.

Since the reaction tube 21 inclined with respect to the horizontal axis of rotation rotates in the R direction while drawing a conical shape as a whole, regardless of whether gas is injected or not, the powder injected into the reaction tube 21 is stirred up, down, left and right (S) can do. That is, when the reaction tube 21 rotates, the reaction tube 21 has a radius corresponding to the length in the vertical direction between the injection shaft 37 and the connection shaft 43 based on the injection shaft 37, and the second cover 41) rotates in a conical shape at the other end of the reaction tube 21 formed thereon. Due to this, the powder can be uniformly distributed in the reaction tube 21 so that the stirring (S) of the powder in the reactor 21 can be made generally.

In this way, since the stirring (S) of the powder is generally performed in the reaction tube 21 according to the first embodiment, it is possible to deposit a thin film on the powder with a uniform thickness.

And, by uniformly distributing the powder in the reaction tube 21, the powder moves toward the second opening 27 in the moving direction of the gas, and the second filter 33 installed on the side of the second opening 27 removes the powder. blockage problems can be suppressed.

[Second Embodiment]

Meanwhile, in the first embodiment, an example in which the reaction tube 21 is installed inclined at a predetermined angle with respect to the horizontal axis of rotation has been disclosed, but is not limited thereto. For example, as shown in FIGS. 7 and 8, in the second embodiment, while the reaction tube 21 is installed horizontally with respect to the horizontal axis of rotation, the powder is uniformly distributed in the reaction tube 21 so that the reactor ( 21), the stirring (S) of the powder can be made generally.

7 is a view showing a powder ALD device 200 including a reactor 20 having a twisted rotation axis according to a second embodiment of the present invention. And FIG. 8 is a view showing the rotation of the reactor 20 of FIG.

Referring to FIGS. 7 and 8 , the powder ALD device 200 according to the second embodiment includes a heat source 10 for supplying heat, and heat supplied from the heat source 10 to perform ALD on the surface of the powder provided therein. It includes a reactor 20 to perform and a motor 50 connected to the reactor 20 via a driving shaft 51 to rotate the reactor 20 . Here, the reactor 20 includes a reaction tube 21, a first cover 35 and a second cover 41. The reaction tube 21 has a first opening 25 and a second opening 27 formed in communication with each other. The first cover 35 covers the first opening 25, and an injection shaft 37 for injecting gas is formed to protrude outward from the first opening 25, and when rotated, the injection shaft 37 It is used as the axis of rotation. And the second cover 41 covers the second opening 27, and the connection shaft 43 connected to the driving shaft 51 of the motor 50 is formed to protrude outward from the second opening 27. and the connecting shaft 27 is twisted with respect to the injection shaft 37.

In this way, since the injection shaft 37 and the connecting shaft 43 of the reactor 20 according to the second embodiment are twisted, the reactor 20 rotates and stirs the powder inside up, down, left and right by itself (S) can be performed.

The powder ALD device 200 according to the second embodiment may further include a link shaft 45 and a chamber 80 .

As described above, the reactor 20 includes the reaction tube 21, the first cover 35 and the second cover 41, the first filter 31, the second filter 33 and the link shaft 45 ) may be further included.

The reaction tube 21 has a cylindrical tube shape with first and second openings 25 and 27 formed on both sides. Although not shown, the reaction tube 21 may include a plurality of stirring blades formed on an inner circumferential surface so as to stir the powder injected therein while rotating, as shown in FIG. 2 . A plurality of stirring blades may be formed to protrude toward the center of the inner circumferential surface of the reaction tube 21 .

The reaction tube 21 is installed horizontally with respect to the rotation shaft in the horizontal direction.

The first and second openings 25 and 27 of the reaction tube 21 are sealed by first and second covers 35 and 41, respectively.

The first cover 35 is coupled to the first opening 25 via the first filter 31 . An injection shaft 37 having an injection port 39 communicating with the inside of the reaction tube 21 is formed on the first lid 35 . A gas required for the ALD process is injected into the reaction tube 21 through the inlet 39 . The injection shaft 37 is supported so that the reaction tube 21 can rotate. That is, the injection shaft 37 is used as a rotation shaft when the reaction tube 21 rotates.

The second cover 41 is coupled to the second opening 27 via the second filter 33 . A connecting shaft 43 is formed at the center of the second cover 41 . The connecting shaft 43 is connected to the drive shaft 51 of the motor 50 that rotates the reactor 20 .

The motor 50 provides a driving force necessary for rotation of the reaction tube 21 through the drive shaft 51 . The drive shaft 51 is coaxial with the injection shaft 37 . Because of this, since the drive shaft 51 and the connection shaft 43 are shifted from each other, the drive shaft 51 and the connection shaft 43 are connected via the link shaft 45.

And the chamber 80 contains the heat source 10 and the reactor 20 . The chamber 80 makes the reactor 20 in a vacuum state during the ALD process.

The reaction tube 21 according to the second embodiment is horizontally interposed between the first and second covers 35 and 41.

The injection shaft 37 and the connection shaft 43 are formed as horizontal axes, respectively, and the injection shaft 37 is formed at a position spaced apart from the central axis of the reaction tube 21 . The reason why the injection shaft 37 is formed in this way is to rotate the reaction tube 21 eccentrically about the injection shaft 37 . By rotating the reaction tube 21 eccentrically, the powder can be uniformly distributed in the reaction tube 21 so that the powder is stirred (S) in the reactor 21 generally. For example, when the injection shaft 37 is formed at an upper portion away from the center of the first cover 35, the connecting shaft 43 may be formed at a lower portion of the second cover 41.

Specifically, it can be assumed that gas is injected into the rotating reactor 20 through the first opening 25 and discharged through the second opening 27 in a state in which powder is supplied to the inside of the reactor 20. When the powder is stirred, the powder is basically stirred up and down by the stirring blades.

Since the reaction tube 21 rotates in the R direction eccentrically with respect to the horizontal axis of rotation, regardless of whether gas is injected, the powder introduced into the reaction tube 21 can be stirred (S) up, down, left and right. Due to this, the powder can be uniformly distributed in the reaction tube 21 so that the stirring (S) of the powder in the reactor 21 can be made generally.

In this way, since the stirring (S) of the powder is generally performed in the reaction tube 21 according to the second embodiment, a thin film can be deposited on the powder with a uniform thickness.

And, by uniformly distributing the powder in the reaction tube 21, the powder moves toward the second opening 27 in the moving direction of the gas, and the second filter 33 installed on the side of the second opening 27 removes the powder. blockage problems can be suppressed.

On the other hand, the embodiments disclosed in this specification and drawings are only presented as specific examples to aid understanding, and are not intended to limit the scope of the present invention. In addition to the embodiments disclosed herein, it is obvious to those skilled in the art that other modifications based on the technical idea of the present invention can be implemented.

10: heat source
20: reactor
21: reaction tube
25: first opening
27: second opening
31: first filter
33: second filter
35: first cover
37: injection shaft
39: inlet
41: second cover
43: connecting shaft
45: link axis
50: motor
51: drive shaft
80: chamber
100, 200: powder ALD device

Claims (12)

a reaction tube formed with a first opening and a second opening to communicate with each other;
a first cover that covers the first opening, has an injection shaft for injecting gas protrudes outward from the first opening, and the injection shaft is used as a rotation shaft during rotation; and
A second cover covering the second opening and having a connection shaft connected to the driving shaft of the motor protrude outward from the second opening, and the connection shaft is twisted with respect to the injection shaft; includes,
The reaction tube is horizontally interposed between the first and second covers, and the injection shaft is formed on the first cover to be eccentric with respect to the central axis of the reaction tube. According to claim 1,
The reactor for a powder ALD device, characterized in that the injection shaft and the connection shaft are formed on the first and second covers in parallel with each other as horizontal axes. According to claim 2,
The reactor for a powder ALD device, characterized in that the injection shaft and the connecting shaft are offset from each other on the same axis. delete According to claim 3,
The injection shaft is a reactor for a powder ALD device, characterized in that located on the same axis as the drive shaft of the motor. According to claim 5,
a link shaft connecting a drive shaft of the motor positioned on the same axis as the injection shaft and the connecting shaft;
A reactor for a powder ALD device, characterized in that it further comprises. According to claim 1,
a first filter interposed between the first opening and the first cover; and
a second filter interposed between the second opening and the second cover;
A reactor for a powder ALD device, characterized in that it further comprises. a heat source that supplies heat;
A reactor rotatably installed inside the heat source and receiving heat from the heat source to perform atomic layer deposition (ALD) on the surface of the powder provided therein; and
A motor connected to the reactor via a drive shaft to rotate the reactor;
The reactor is
a reaction tube formed with a first opening and a second opening to communicate with each other;
a first cover that covers the first opening, has an injection shaft for injecting gas protrudes outward from the first opening, and the injection shaft is used as a rotation shaft during rotation; and
A second cover covering the second opening and having a connection shaft connected to the drive shaft of the motor protrude outward from the second opening, and the connection shaft is twisted with respect to the injection shaft; Includes,
The powder ALD device, characterized in that the reaction tube is horizontally interposed between the first and second covers, and the injection shaft is formed on the first cover to be eccentric with respect to the central axis of the reaction tube. The method of claim 8, wherein the reactor,
The powder ALD device, characterized in that the injection shaft and the connection shaft are formed on the first and second lids as horizontal axes and parallel to each other. According to claim 9,
Powder ALD device, characterized in that the injection shaft and the connecting shaft are offset from each other on the same axis. According to claim 9,
The injection shaft is a powder ALD device, characterized in that located on the same axis as the drive shaft of the motor. According to claim 11,
a link shaft connecting a drive shaft of the motor positioned on the same axis as the injection shaft and the connecting shaft;
Powder ALD device further comprising a.

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