KR20240048761A - Positioning device for substrate support - Google Patents

Abstract

The present invention is a substrate support position control device that adjusts the position of a substrate support that supports the bottom of a substrate while placed inside a processing chamber of a substrate processing system, comprising: a rod-shaped support rod coupled to the center bottom of the substrate support; A carrier portion coupled to the lower end of the support rod; Servo motors provided at each lower end of the vertical rail unit to independently control forward and reverse rotation of the ball screw; a lifting member that is screwed into the ball screw of the vertical rail unit and moves up and down along the ball screw according to forward and reverse rotation of the servo motor; And a set that transmits a tilting or moving motion generated on a horizontal axis parallel to the side tangent of the carrier part by the raising and lowering of the lifting member, with one end coupled to the lifting member and the other end coupled to the side of the carrier part, to the carrier part. It is characterized by including the above tilting motion transmission unit.

Description

Positioning device for substrate support}

The present invention relates to a substrate support position control device, and more specifically, to check the flatness of the substrate support on which the substrate is mounted at all times and automatically correct the flatness of the substrate support, thereby improving the leveling precision of substrate processing and process efficiency. and a substrate support positioning device that improves yield and, in particular, maintains leveling precision consistently by minimizing mechanical wear of the leveling joint over time and minimizes the generation of particles due to wear.

In general, devices for processing substrates such as semiconductor wafers can be largely divided into thin film deposition devices for forming thin films and etching devices for forming circuits by finely cutting off the thin films formed on the substrate.

Among these, thin film deposition equipment is divided into a chemical method of synthesizing solid materials such as thin films or particles through a chemical reaction from gaseous raw materials, and a physical method of depositing particles to be deposited on a substrate using various physical methods. .

Chemical vapor deposition, one of the above chemical methods, places a substrate in a reaction chamber blocked from the outside and injects gas raw materials through the gas supply section, causing thermal decomposition by the heat supplied from the heating section and changing the properties of the substrate. As a device for forming thin films without forming a thin film, it is widely used not only in semiconductor wafers but also in substrate processing devices for forming TFTs (thin film transistors) of flat panel displays.

The substrate processing apparatus includes a substrate support rod installed at the inner center of the process chamber, and a substrate support rod fixed to an upper end of the substrate support rod on which a substrate such as a semiconductor wafer is seated.

In the past, whenever the flatness of the substrate support was distorted, the process had to be stopped, the leveling adjusted, and then the vacuum had to be created again, which caused a problem in that the process efficiency and yield of substrate processing were greatly reduced. Additionally, when adjusting the leveling of the substrate support, there was a problem in that wear between machine components was accelerated and durability was reduced.

(Patent Document 1) US Patent Registration No. 11251067 (Figures 1 and 2)

Accordingly, the present invention was devised to solve the above problems. By checking the flatness of the substrate support on which the substrate is mounted at all times and automatically correcting the flatness of the substrate support, the leveling precision of substrate processing and process efficiency are improved. The purpose is to provide a substrate support positioning device that can improve yield, maintain consistent leveling precision by minimizing mechanical wear of the leveling joint over time, and minimize particle generation due to wear. Do it as

The present invention to achieve the above object relates to a substrate support position adjusting device that adjusts the position of a substrate support that supports the bottom surface of a substrate while placed inside a processing chamber of a substrate processing system.

The present invention includes a rod-shaped support rod coupled to the bottom of the center of the substrate support; A carrier portion coupled to the lower end of the support rod; Servo motors provided at each lower end of the vertical rail unit to independently control forward and reverse rotation of the ball screw; a lifting member that is screwed into the ball screw of the vertical rail unit and moves up and down along the ball screw according to forward and reverse rotation of the servo motor; And a set that transmits a tilting or moving motion generated on a horizontal axis parallel to the side tangent of the carrier part by the raising and lowering of the lifting member, with one end coupled to the lifting member and the other end coupled to the side of the carrier part, to the carrier part. It is characterized by including the above tilting motion transmission unit.

The tilting motion transmission unit includes a bearing housing each coupled to three or more points on the outer surface of the carrier unit; A spherical bearing coupled to one side of the bearing housing and tilted on the X, Y, or Z axis by the raising and lowering movement of the lifting member; A linear shaft axially coupled to the hollow of the spherical bearing; A linear shaft block that is raised and lowered together with the lifting member by having one end coupled to the linear shaft and the other end coupled to the lifting member; A linear shaft bracket that restrains the linear shaft from being separated from the bearing housing while the linear shaft and the spherical bearing are coupled together; And it may include a bearing bracket that restrains the spherical bearing from being separated from the bearing housing while the linear shaft and the spherical bearing are combined.

The axial direction of the linear shaft coupled between the bearing housing and the linear shaft block may be perpendicular to the direction connecting the carrier portion and the lifting member in the horizontal direction.

A base plate is further provided at the top of each vertical rail portion, and the base plate is coupled to the bottom of the processing chamber. A corrugated pipe is further provided between the base plate and the carrier portion, and the support rod is connected to the processing chamber through the corrugated pipe. Can be placed inside.

The bearing housing has a 'ㅗ' shape when viewed in plan, and may be bolted to a flat cutting groove formed around the side surface of the carrier portion.

The base plate is fixed and coupled to the top of each vertical rail portion by bolting so that the tilting or moving motion transmitted to the carrier portion and the support rod through the tilting motion transmission portion is not transmitted to the base plate.

The spherical bearing may be a self-aligning ball bearing or a self-aligning roller bearing.

As described above, the present invention has the effect of improving the leveling precision of substrate processing and improving process efficiency and yield by constantly checking the flatness of the substrate support on which the substrate is mounted and automatically correcting the flatness of the substrate support. There is.

In particular, it has the effect of minimizing mechanical wear of the leveling joint over time, thereby maintaining consistent leveling precision and minimizing the generation of particles due to wear.

1 is a perspective view showing an auto-leveling device of a substrate processing device including a tilting structure of the present invention according to one embodiment.
Figure 2 is a longitudinal cross-sectional view of the main part taken along line 'A-A' of Figure 1
Figure 3 is (a) a perspective view of the main part and (b) an exploded perspective view showing the configuration of the tilting motion transmission unit according to the present invention according to an embodiment.
Figure 4a is a front view of the tilting motion transmission unit according to the present invention, and Figure 4b is a perspective cross-sectional view of the main part taken along line 'B-B' of Figure 4a.
Figure 5 is a longitudinal cross-sectional view along line 'C-C' of Figure 4a showing the operating state of the tilting motion transmission unit according to the present invention, (a) horizontal state, (b) tilting and moving state.

The terms used in this specification are merely used to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as “include” or “have” or “equipped” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in this specification. It should be understood that this does not preclude the existence or addition of other features, numbers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined herein, all terms used herein, including technical or scientific terms, have the same meaning as generally understood by a person of ordinary skill in the technical field to which the present invention pertains.

Terms defined in commonly used dictionaries should be interpreted as having meanings consistent with the meanings they have in the context of the related technology, and unless clearly defined in this specification, should not be interpreted in an idealized or overly formal sense. It shouldn't be.

Hereinafter, the configuration and operational relationship of the auto-leveling device of the substrate processing device including the tilting structure of the present invention will be examined in detail with reference to the attached drawings.

Figure 1 is a perspective view showing an auto-leveling device of a substrate processing apparatus including a tilting structure of the present invention according to an embodiment, Figure 2 is a longitudinal cross-sectional view of the main part taken along line 'A-A' of Figure 1, and Figure 3 is a schematic diagram of the present invention. (a) a perspective view of the main part and (b) an exploded perspective view showing the configuration of the tilting motion transmission unit according to an embodiment, FIG. 4A is a front view of the tilting motion transmission unit according to the present invention, and FIG. 4B is 'B-B' of FIG. 4A. 'This is a cross-sectional perspective view of the line's lumbar region.

As shown in FIGS. 1 to 4, the auto-leveling device of the substrate processing apparatus including the tilting structure according to an embodiment of the present invention first supports the bottom of the substrate and includes a substrate support (100) for processing the substrate, such as thin film deposition. ) is provided. The substrate support 100 supports the bottom of the substrate while placed inside the processing chamber.

Additionally, a rod-shaped support rod 200 is provided on the bottom of the center of the substrate support 100. The support rod 200 may be provided in the shape of a pipe with a hollow interior.

Additionally, a carrier portion 320 is coupled to the lower end of the support rod 200. That is, the tilting (rotational movement) or moving (linear movement) motion in the vertical axis (Z-axis) direction transmitted through the carrier unit 320 by control of the servo motor 600, which will be described later, is applied to the support rod. By being transmitted to (200), the flatness of the substrate support 100 coupled to the top of the support rod 200 is finally corrected.

Additionally, a plurality of tilting motion transmission units 800 are coupled to the side surface of the carrier unit 320. Specifically, one end of the tilting motion transmitting unit 800 is coupled to the side of the carrier unit 320, thereby causing tilting that occurs in the vertical axis (Z-axis) direction according to the raising and lowering movement of the vertical rail unit and the lifting member 400. Alternatively, the moving motion is transmitted to the carrier unit 320.

According to one embodiment, a total of three tilting motion transmission units 800 are provided, one at each 120 degree position on the side of the carrier unit 320. However, the present invention is not limited to this, and depending on the design specifications of the device, the tilting motion transmission unit 800 may be provided in plurality of three or more around the carrier unit 320.

At this time, the tilting motion transmission unit 800 has one end coupled to the lifting member 400 and the other end coupled to the side of the carrier part 320, and the carrier part is moved up and down by the lifting member 400. The tilting or moving motion generated around the horizontal axis (Y-axis) parallel to the side tangent of 320 is transmitted to the carrier unit 320.

According to one embodiment, the tilting motion transmission unit 800 includes a bearing housing 810 coupled to three or more points of the outer surface of the carrier unit 320, and a bearing housing 810 coupled to one side of the bearing housing 810. A spherical bearing 840 that is tilted on the and a linear shaft block 820 that is raised and lowered together with the lifting member 400 by having one end coupled to the linear shaft 830 and the other end coupled to the lifting member 400, and the linear shaft 830 and the spherical surface. A linear shaft bracket 860 that restrains the linear shaft 830 from being separated from the bearing housing 810 in a state in which the bearing 840 is coupled, and a state in which the linear shaft 830 and the spherical bearing 840 are coupled. It is configured to include a bearing bracket 850 that restrains the spherical bearing 840 from being separated from the bearing housing 810.

At this time, the bearing housing 810 has a ‘ㅗ’ shape when viewed in plan, and is bolted to the planar cutting groove 320a formed around the side surface of the carrier part. (see Figures 3b, 6a)

In addition, the axial direction (Y-axis direction) of the linear shaft 830 coupled between the bearing housing 810 and the linear shaft block 820 is the direction connecting the carrier portion 320 and the lifting member 400 (X axial direction) and orthogonal to the horizontal direction. (see Figure 4)

According to one embodiment, the spherical bearing 840 may be a simple spherical bearing without balls or rollers, or a self-aligning ball bearing or a self-aligning roller bearing may be used.

In addition, a fixing screw 870 is fastened to the threaded hole (unmarked) of the linear shaft 830 through the linear shaft block 820 to prevent the linear shaft 830 from being separated from the linear shaft block 820. do. (see Figure 5a, b)

In addition, a vertical rail portion 500 is provided on the opposite side of the tilting motion transmitting portion 800 of the lifting member 400, and each lifting member 400 includes a ball screw vertically disposed inside the vertical rail portion 500. By being coupled to 510, the lifting member 400 is raised and lowered according to the forward and reverse rotation of the ball screw 510.

In addition, a servo motor 600 is provided at each lower end of the vertical rail portion 500, and each servo motor 600 operates in the forward and reverse directions of the ball screw 510 provided inside the vertical rail portion 500. Rotation is controlled independently.

That is, each of the lifting members 400 is coupled to the vertical rail part 500 to be able to move up and down. A ball screw 510 is provided at the center of each vertical rail part 500, so that the lifting members 500 can be raised and lowered. (400) is respectively penetrated and coupled to the screw of the ball screw (510).

At this time, a servo motor 600 is shaft-coupled at each lower end of the vertical rail portion 500 to rotate the ball screw 510, ultimately controlling the forward and reverse rotation of the servo motor 600. The ball screw 510 coupled to the rotation shaft (not shown) of the servo motor 600 is also rotated forward and reverse, and eventually the lifting member 400 is raised and lowered on the ball screw 510.

Meanwhile, a base plate 310 is provided on the top of each vertical rail portion 500, and the base plate 310 is fixedly coupled to the bottom of the processing chamber. At this time, the three fixing protrusions 311 integrally protruding along the edge of the base plate 310 are fixedly coupled to the upper end of the vertical rail portion 501 by means of fastening bolts.

As a result, the tilting or moving motion transmitted to the carrier part 400 and the support rod 200 through the tilting motion transmission part 800 by the raising and lowering movement of the lifting member 400 is not transmitted to the base plate 310 at all. Avoid doing so. That is, the fixing protrusion 311 of the base plate 310 is completely fixed to the top 501 of the vertical rail portion 500 by fastening bolts so as not to move. As a result, the tilting or moving motion is transmitted to the carrier unit 320 and the support rod 200 only through the tilting motion transmission unit 800, so the flatness of the substrate support 100 is ultimately maintained only through the tilting motion transmission unit 800. You have total control.

Accordingly, the present invention reduces the mechanical strength of the device, the decrease in precision due to wear, and the generation of dust, which were caused by the pivot joint of the conventional base plate being exposed to continuous wear and fatigue load by using the above-described fixing structures 311 and 501. Such evils are prevented.

In addition, a corrugated pipe 330 is provided between the base plate 310 and the carrier portion 320, so that the support rod 200 coupled to the carrier portion 320 is disposed inside the processing chamber through the corrugated pipe 330. do. At this time, the corrugated pipe 330 plays a role in maintaining airtightness inside the processing chamber.

Meanwhile, although not shown in the drawing, the substrate support 100 may be further equipped with a flatness sensor (not shown). Accordingly, when the flatness of the substrate support 100 is distorted, the control unit (not shown) immediately checks the flatness defect at all times and independently controls each servo motor 600, ultimately controlling the substrate support 100 and the The flatness of the substrate mounted on the upper surface of the substrate support 100 is automatically corrected (auto-leveling).

In addition, according to an embodiment of the present invention, the attached drawing illustrates a vacuum deposition apparatus for a semiconductor substrate (wafer) as an example of a substrate processing apparatus. In this case, the shape of the substrate support 100 is such that it can seat the semiconductor substrate. It is preferable that it is formed in a circular shape so that it can be formed.

In addition, the substrate support 100 may be formed not only in a circular shape but also in a polygonal shape. For example, the substrate support 100 of this polygonal shape can seat a substrate for solar cells, an LED (light emitting diode) substrate, or a substrate for flat panel displays such as LCD and OLED as an object to be processed.

Hereinafter, with reference to FIG. 5, the operational relationship of the tilting motion transmission unit according to the present invention will be examined as follows.

FIG. 5 is a longitudinal cross-sectional view along line ‘C-C’ of FIG. 4A showing the operating state of the tilting motion transmission unit according to the present invention, (a) in a horizontal state and (b) in a tilting and moving state.

First, Figure 5a illustrates a state in which the tilting motion transmission unit 800 according to the present invention is maintained horizontally. In other words, the state in which the tilting motion transmission unit 800 is maintained horizontally means that auto-leveling is not required for the substrate support 100 of the present invention.

Therefore, at this time, the linear shaft block 820 and the spherical bearing 840 of the tilting motion transmission unit 800 are vertically aligned on the Z axis, and the carrier unit 400 coupled to the linear shaft block 820 and The support rod 200 also remains vertically aligned in the Z-axis direction.

Meanwhile, when the flatness of the substrate support 100 is distorted due to external force or other factors in the horizontal state as shown in FIG. 5A, auto leveling is performed.

That is, the servo motor 600 on the side where sagging occurs in the Z-axis direction is driven by the flatness sensor (not shown) of the substrate support 100, and auto-leveling to correct the flatness is automatically performed.

Hereinafter, the auto-leveling process of the present invention will be examined in more detail with reference to FIG. 5B.

First, the servo motor 600 on the side where the deflection occurs in the Z-axis direction is driven to raise the lifting member 400 and the linear shaft block 820 by a distance b. At this time, the linear shaft block 820 and the linear shaft block 820 are raised by the distance b. The bearing housing 810 pivoted by the shaft is also tilted by a certain angle in the -X axis direction around the Y axis.

For example, as shown in FIGS. 5A and 5B, the values of the tilting or moving motion acting on the tilting motion transmission unit 800 can be obtained as follows.

1) As shown in Figure 5a, when the basic distance on the Y-axis from the linear shaft bracket 860 to the linear shaft 830 in the horizontal state before tilting is A, the tilting angle (α )Is,

α = arctan(b/A)

2) As shown in Figure 5b, the moving distance (A') of the linear shaft 830 from the linear shaft bracket 860 after tilting is,

A’ = A/cos(α)

3) The horizontal movement distance (d) on the Y axis of the linear shaft 830 is,

d = A’-A

Therefore, when the lifting member 400 and the linear shaft block 820 are raised by the distance b (moving motion in the Z-axis direction) by driving the servo motor 600, the bearing pivotally coupled to the linear shaft 830 The housing 810 is rotated around the Y axis in the -X axis direction by an angle α.

Therefore, the tilting motion transmission unit 800 of the present invention not only operates very smoothly because it has complete freedom in the tilting and moving motions that are generated complexly in the X, Y, or Z axis directions by the spherical bearing 840. Tilting and moving motions in the X, Y, or Z axis directions can be stably cushioned and supported by the lifting and lowering movement of the lifting member 400.

As a result, the chronic problems of the past, such as mechanical wear and fatigue load problems occurring in pivot joints and bearing pins, and load rate problems applied to servo motors, can be greatly improved, so the present invention provides more accurate and stable auto-leveling. do.

As described above, the present invention can always check the flatness of the substrate support 100 and automatically correct the leveling by transmitting a tilting or moving motion to the substrate support through the tilting motion transmission unit.

Through this, it not only prevents various types of defects such as poor substrate processing or damage to the substrate that may be caused by poor flatness of the conventional substrate support, but also provides the beneficial advantage of improving the precision and yield of the substrate processing process. .

In addition, the present invention is not limited to just one embodiment described above, and the same effect can be created even when changing the detailed configuration, number, and arrangement structure of the device, so those skilled in the art will understand the present invention. It is stated that addition, deletion, and modification of various configurations are possible within the scope of the technical idea.

100: substrate support 200: support rod
310: Base plate 311: Fixing protrusion
320: carrier part 330: corrugated pipe
400: Elevating member 500: Vertical rail part
501: Top (of vertical rail part) 510: Ball screw
600: Servo motor 800: Tilting motion transmission unit
810: Bearing housing 820: Linear shaft block
830: Linear shaft 840: Spherical bearing
850: Bearing bracket 860: Linear shaft bracket
870: fixing screw

Claims (7)

In the substrate support position adjusting device that adjusts the position of the substrate support that supports the bottom surface of the substrate while placed inside the processing chamber of the substrate processing system,
A rod-shaped support rod coupled to the bottom of the center of the substrate supporter;
A carrier portion coupled to the lower end of the support rod;
Servo motors provided at each lower end of the vertical rail unit to independently control forward and reverse rotation of the ball screw;
a lifting member that is screwed into the ball screw of the vertical rail unit and moves up and down along the ball screw according to forward and reverse rotation of the servo motor; and
Three or more devices that transmit a tilting or moving motion generated on a horizontal axis parallel to the side tangent of the carrier portion by the raising and lowering of the lifting member, with one end each coupled to the lifting member and the other end coupled to the side of the carrier portion, to the carrier portion. A substrate support position control device comprising a tilting motion transmission unit. According to claim 1,
The tilting motion transmission unit,
Bearing housings each coupled to three or more points on the outer surface of the carrier unit;
A spherical bearing coupled to one side of the bearing housing and tilted on the X, Y, or Z axis by the raising and lowering movement of the lifting member;
A linear shaft axially coupled to the hollow of the spherical bearing;
A linear shaft block that is raised and lowered together with the lifting member by having one end coupled to the linear shaft and the other end coupled to the lifting member;
A linear shaft bracket that restrains the linear shaft from being separated from the bearing housing while the linear shaft and the spherical bearing are coupled together; and
A substrate support position adjusting device comprising a bearing bracket that restrains the spherical bearing from being separated from the bearing housing while the linear shaft and the spherical bearing are combined. According to claim 2,
A substrate support positioning device, characterized in that the axial direction of the linear shaft coupled between the bearing housing and the linear shaft block is perpendicular to the direction connecting the carrier portion and the lifting member in the horizontal direction. According to claim 1,
A base plate is further provided at the top of each vertical rail portion, and the base plate is coupled to the bottom of the processing chamber,
A corrugated pipe is further provided between the base plate and the carrier portion,
A substrate support position control device, characterized in that the support rod is disposed inside the processing chamber through the corrugated pipe. According to claim 1,
The bearing housing has a 'ㅗ' shape when viewed in plan, and is bolted to a flat cutting groove formed around the side surface of the carrier part. According to claim 1,
The base plate is fixed and coupled to the top of each vertical rail portion by bolting so as not to move, so that the tilting or moving motion transmitted to the carrier portion and the support rod through the tilting motion transmission portion is not transmitted to the base plate. Support position adjustment device. According to claim 1,
A substrate support positioning device, characterized in that the spherical bearing is a self-aligning ball bearing or a self-aligning roller bearing.