KR100942461B1 - Semiconductor manufafturing equipments with automatic teaching apparatus of wafer transfer robot and method for teaching of the same - Google Patents

Abstract

TECHNICAL FIELD This invention relates to the semiconductor manufacturing equipment provided with the automatic teaching apparatus of a substrate transfer robot, and its teaching method. The semiconductor manufacturing facility includes a processing unit disposed in parallel with the moving direction of the substrate transfer robot, and at least one processing unit disposed inclined at an angle to the moving direction of the substrate transfer robot. The substrate transfer robot moves left and right in parallel with the processing units arranged in parallel even when the teaching setting of the processing units arranged inclined. Therefore, the automatic teaching apparatus acquires the coordinate data of the hole with respect to the center position of the plate by acquiring the image data with the vision camera for setting the teaching of the processing unit arranged obliquely, and moves the robot arm to approach the coordinate value of the hole within an error range. Teaching and setting the robot arm by moving left and right in the axial direction and at an angle to the central axis. According to the present invention, teaching setting of the robot arm to at least one processing unit arranged obliquely is possible.

Semiconductor manufacturing equipment, automatic teaching device, vision camera, coordinate tracking, processing unit

Description

Semiconductor manufacturing equipment having automatic teaching device of substrate transfer robot and teaching method thereof

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a semiconductor manufacturing facility. More particularly, in a semiconductor manufacturing facility having a plurality of processing units and a substrate transfer robot, a semiconductor manufacturing facility including an automatic teaching apparatus for teaching a substrate transfer robot using a vision system. And a teaching method thereof.

The present invention also relates to a semiconductor manufacturing equipment and method for automatic teaching of a substrate transfer robot with respect to at least one processing unit disposed inclined with the movement direction of the substrate transfer robot.

In the semiconductor manufacturing process, a photolithography process forms a desired resist pattern by applying a resist solution to a wafer substrate and exposing and developing using a photo mask. This photolithography process transfers a wafer substrate through a substrate transfer device to a processing unit (or process chamber) that processes resist solution application, exposure and development. Therefore, the substrate transfer apparatus needs to set the position of the transfer robot in order to supply the wafer accurately to each processing unit.

For example, a semiconductor manufacturing facility such as a spinner system or a scrubber has a plurality of processing units, and the wafer is transferred to the processing unit by a transfer robot. The processing unit advances each process and is again transferred to the outside by the transfer robot. For example, in a facility that performs a spin coater process, a wafer is moved into a plurality of processing units that each perform a process such as baking, application, and development by a transfer robot. At this time, it is very important that the wafer is correctly placed at the set position of the plate in the processing unit. If the wafer is incorrectly positioned on the plate in the bake module or the application module, process errors such as failure to uniformly heat the entire wafer or uniform application of the photoresist occur.

For this purpose, a teaching operation is performed to adjust the position of the transfer robot before the process is performed so that the wafer can be loaded to the correct position of the plate or spin chuck in the processing unit. In addition, while the transfer robot transfers the wafer, the movement position of the transfer robot for loading the wafer into each process module often deviates from the initially set position due to the collision of the input window or the plate of the processing unit. In this case, it is usually necessary to reset the teaching of the transfer robot in each process module.

Referring to FIG. 1, the semiconductor manufacturing facility 10 includes a plurality of processing units 12 arranged in parallel with the moving direction of the substrate transfer robot 20 (that is, the Y axis direction). The substrate transfer robot 20 includes at least one robot arm 22. Therefore, the substrate transfer robot 20 transfers the wafer substrate through the injection window 14 of each processing unit 12 using the robot arm 22. At this time, the robot arm 22 needs to be taught in order to transfer the wafer to the correct position of each of the processing units 12, and for this purpose, the teaching jig 30 is mounted on the robot arm 22.

Teaching zig 30 is provided in a form that can be fixedly installed, mounted, detachable to the robot arm 22 of the substrate transfer robot 20. Then, the robot arm 22 is driven to detect the position in the X, Y, and Z axis directions, the position of the robot arm 22 is corrected from the detected position information, and the teaching is performed.

To this end, the teaching jig 30 includes a vision camera 32 capable of imaging in the center lower direction. The vision camera 32 acquires image data for the plate (not shown) of the processing unit 12 by imaging in the direction of the center lower end of the jig 30. The obtained image data is provided to the controller (not shown) through wired or wireless communication.

The controller is a controller that controls the vision camera 32 and the substrate transfer robot 20. The controller receives the image data from the vision camera 32 and detects X and Y axis coordinate data of the center position of the plate of the processing unit 12. do. Therefore, the control unit detects and corrects the positions of the robot arms 22 about the X, Y, and Z axes so that the wafer can be supplied to the precise center position of each processing unit 12 using the vision camera 32. Set.

However, the teaching jig 30 can be used only when the plurality of processing units 12 are arranged in parallel with the left and right moving directions of the substrate transfer robot 20.

Therefore, when at least one processing unit 12 is disposed to be inclined with the movement direction of the substrate transfer robot 20 according to an environment such as an installation location of the semiconductor manufacturing facility 10, accurate teaching setting of the robot arm 22 is performed. There is a difficult problem.

SUMMARY OF THE INVENTION An object of the present invention is to provide a semiconductor manufacturing facility having at least one processing unit inclined with the direction of movement of the substrate transfer robot and a teaching method thereof.

It is another object of the present invention to provide a semiconductor manufacturing facility having a processing unit in which at least one processing unit is disposed to be inclined with the movement direction of the substrate transfer robot and a method of using the vision system to teach the substrate transfer robot thereof.

It is still another object of the present invention to provide a semiconductor manufacturing facility and method for automatically teaching by tracking the center position of the plate with respect to at least one processing unit disposed obliquely to the moving direction of the substrate transfer robot with the tilted angle as an axis. .

In order to achieve the above objects, the automatic teaching apparatus of the present invention is characterized by processing automatic teaching for at least one processing unit which is disposed to be inclined with the moving direction of the substrate transfer robot. Such automatic teaching device enables automatic teaching for at least one processing unit which is arranged obliquely.

The automatic teaching apparatus of the present invention sets a teaching for each of the processing units in a substrate transfer device of a semiconductor manufacturing facility including a plurality of processing units. Such automatic teaching apparatus includes: a teaching jig mounted on a robot arm of the substrate transfer apparatus; A vision camera installed at the center lower surface of the jig to acquire image data of the plate of the processing unit; Receiving the image data from the vision camera, when setting the teaching of the robot arm to at least one processing unit disposed inclined at a predetermined angle with the movement direction of the substrate transfer robot of the processing unit, the plate from the image data Coordinate values when the robot arm coincides with the center position of the plate by acquiring X-axis and Y-axis coordinate values for the central position of the target, and moving the robot arm in a scanning manner with the obtained coordinate values as a target. It includes a control unit for storing.

In one embodiment, the control unit; The robot arm is controlled to track the coordinate value by moving left and right in the Y axis direction and simultaneously moving back and forth in the X axis direction about the predetermined angle.

In another embodiment, the control unit; When setting the teaching of the robot arm with respect to the remaining processing unit arranged in parallel with the moving direction of the substrate transfer robot among the processing units, the robot arm is stored when the coordinate value coincides with the center position of the plate. Control to teach automatically.

In another embodiment, the control unit; If the robot arm moves to the coordinate value and is within an allowable error range between the center position of the plate and the robot arm, the robot arm is corrected by a deviation between the coordinate value within the error range and the coordinate value of the center position of the plate. Match to the central position of.

According to another feature of the invention, at least one processing unit of the plurality of processing units having a plate on which the semiconductor substrate is mounted therein at least one processing unit disposed to be inclined at an angle with the movement direction of the substrate transfer robot, and In a semiconductor manufacturing facility having a remaining processing unit arranged in parallel with a moving direction, a teaching method of an automatic teaching apparatus for teaching setting the robot arm of the substrate transfer robot with respect to the processing units, respectively. According to this method, image data for a plate of the processing unit arranged obliquely is obtained. The X-axis and Y-axis coordinate values for the central position of the plate are obtained from the image data. Subsequently, the robot arm is moved in a scanning manner with respect to the X and Y axis coordinate values to store coordinate values when the robot arm coincides with the center position of the plate.

In one embodiment, moving the robot arm in a scan manner; Repeating the movement of the robot arm in the X axis direction and the left and right movement of the robot arm in the Y axis direction with respect to the central axis until the current coordinate value of the moving robot arm is within an error range with the center position of the plate. do.

In another embodiment, when the current coordinate value of the robot arm is within the error range, the robot arm is taught by correcting a deviation between the current coordinate value and the X and Y axis coordinate values.

In another embodiment, the teaching method; When setting the teaching of the robot arm with respect to the remaining processing unit arranged in parallel with the moving direction of the substrate transfer robot among the processing units, the robot arm is set to the X axis and the Y axis coordinate values by the X axis and the Y axis. Teaching the robot arm by storing the coordinate value when the current coordinate value coincides with the center position of the plate by linearly moving in the axial direction.

As described above, the semiconductor manufacturing equipment of the present invention includes at least one processing unit disposed obliquely, and when setting the teaching of the at least one processing unit disposed obliquely, the tilted angle is scanned back and forth, and from side to side as an axis to plate By tracking the central position of the robot arm teaching setting of at least one processing unit arranged obliquely is possible.

In addition, the automatic teaching apparatus can teach the robot arm to at least one processing unit which is disposed to be inclined at a predetermined angle with the movement path of the substrate transfer robot by using the vision camera.

The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be interpreted as being limited by the embodiments described below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the components in the drawings, etc. have been exaggerated to emphasize a more clear description.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 2 to 6.

2 is a diagram showing a schematic configuration of a semiconductor manufacturing facility having a processing unit arranged diagonally according to the present invention.

Referring to FIG. 2, semiconductor manufacturing facility 100 includes a plurality of processing units 102, 104 and at least one robotic arm 112 for supplying a wafer substrate to processing units 102, 104. It includes a substrate transfer robot 110. At least one of the processing units 102 and 104 is disposed to be inclined at a predetermined angle θ to the left and right linear movement direction (ie, Y axis direction) of the substrate transfer robot 110. In addition, the remaining processing units 102 are disposed parallel to the left and right linear movement directions of the substrate transfer robot 110.

The semiconductor manufacturing equipment 100 also includes automatic teaching devices 120 to 124 for processing the teaching settings of the processing unit 104 disposed obliquely in accordance with the present invention. Automatic teaching devices (120 to 124) is a teaching jig 120 mounted on the robot arm 112, the vision camera 122 is installed on the lower center of the jig 120, and the vision camera 122 and wired or And a control unit 124 for wireless communication (eg, Bluetooth, etc.).

Specifically, each of the processing units 102, 104 includes a plate 106 on which a wafer is seated, and the plate 106 is provided with a hole 108 indicating a central position.

The substrate transfer robot 110 includes at least one robot arm 112 having a plurality of arms, and the jig 120 for teaching is mounted on the robot arm 112. Thus, the robot arm 112 is rotated back and forth, left and right and rotated to teach the respective processing units 102 and 104. In addition, the substrate transfer robot 110 linearly moves from side to side in parallel with the processing units 102 and 104. In this case, the substrate transfer robot 110 maintains a predetermined angle θ with the processing unit 104 in which the movement direction is disposed inclined in the case of the processing unit 104 disposed inclined among the processing units 102 and 104. Ideally, the substrate transfer robot 110 moves linearly in the same Y-axis direction as the rest of the processing units 102 when teaching the processing unit 104 which is disposed obliquely. Therefore, when teaching the processing unit 104 is disposed obliquely there is a section that can not drive the robot arm 112 only by the rectangular coordinate system by the vision camera 122, there must be consideration for a certain angle (θ).

That is, in order to correct for a predetermined angle θ when teaching the processing unit 104 disposed to be inclined, the present invention tracks a rectangular coordinate system by the vision camera 122 in a scan manner to perform a plate (scan). Search for a central location 108 of 106. To this end, the control unit 124 receives the image data from the vision camera 122, detects the coordinate value of the hole 108 in the center position of the plate 106, and the robot arm 112 at a predetermined angle (θ) Teaching is set by scanning the robot arm back and forth in the X-axis direction and moving left and right around the θ axis about the inclined axis to move the origin of the image data to the position of the hole 108. Details will be described in detail with reference to FIGS. 3 to 6.

In addition, the teaching jig 120 is mounted to the robot arm 112 and includes a vision camera 122 that picks up in the center lower direction. The vision camera 122 transmits the image data to the control unit 124 through wired or wireless communication so as to capture the plate 106 and obtain a coordinate value for the hole 108 at the plate 106 center position.

The controller 124 transmits data and control signals to the vision camera 122 through wire or wireless communication (for example, Bluetooth). In addition, the controller 124 controls the front, rear, rear, and rotational movements of the substrate transfer robot 110 to teach the robot arm 112 for each of the processing units 102 and 104.

Therefore, the automatic teaching apparatuses 120 to 124 of the present invention have an X axis direction centering on an axis in which the robot arm is inclined at a certain angle θ when teaching to the processing unit 104 disposed to be inclined at a certain angle θ. The position of the hole 108 is tracked while moving back and forth and moving left and right in the Y-axis direction about the θ axis.

Specifically, referring to FIG. 3, the teaching jig 120 is mounted on the robot arm 112 and actually teaches the substrate transfer robot 110 to teach the processing unit 104 on which the robot arm 112 is inclined. ) Is rotated by a predetermined angle (θ) and introduced into the processing unit 104. Accordingly, although the X-axis coordinates of the vision camera 122 and the X-axis coordinates of the robot arm 112 in the moving direction coincide, the Y-axis coordinates of the vision camera 122 and the movement direction of the robot arm 112 do not match. According to the Y-axis coordinates, deviations are generated as much as rotated by a predetermined angle θ. That is, the Y axis direction of the vision camera 122 and the Y axis direction of the robot arm 112 are different from each other.

Therefore, the automatic teaching apparatuses 120 to 124 of the present invention have a center position of the plate 106 in order to correct the deviation of the X and Y axis coordinate values by the vision camera 122 by a predetermined angle θ. If the position of the hole 108 in the scan is traced and the position of the moving robot arm 112 is close to the hole 108 within the error range, X for the position of the robot arm 112 at that time, Set up teaching by saving Y axis coordinate value.

Also, as shown in FIG. 4, the image data 130 includes a position 134 at which the hole 108 representing the central position of the plate 106 is photographed, and an origin 132 of the X and Y axes of the image data 130. As shown in FIG. 5, the teaching of the processing unit 104 is established by moving the robot arm 112 back and forth, and to the left and right so as to coincide. At this time, the constant a represents the movement amount for tracking the position of the hole 108 by moving left and right in the Y axis direction about the θ axis, through which the coordinates of the Y axis with respect to the vision camera 122 can be found. In addition, the constant b represents the movement amount for tracking the position of the hole 108 while moving on the X axis of the robot arm 112, and through this, the coordinates of the X axis with respect to the vision camera 122 can be found. Therefore, the controller 124 moves the robot arm 112 back and forth in the X-axis direction while alternately shifting the Y-axis direction from side to side about the θ axis to track the position of the hole 108.

Therefore, the control unit 124 receives the image data from the vision camera 122 when setting the teaching of the robot arm 112 to the at least one processing unit 104 disposed to be inclined, the central position 108 of the plate 106. Detects the coordinate values of the X-axis and the Y-axis, moves the origin of the image data alternately in the Y-axis direction from the left and right around the θ axis, and moves back and forth in the X-axis direction at the target. 108). In addition, the controller 124 acquires image data again from the position where the robot arm 112 is moved, repeats the above-described process of detecting the coordinate value and tracking the position of the hole 108, and then moves the robot to the position of the hole 108. Teaching is set by storing the X and Y coordinate values when the arm 112 is located.

In addition, the controller 101 sets coordinate values of the X and Y axes when teaching is set for the remaining processing units 102 disposed parallel to the moving direction of the substrate transfer robot 110 among the processing units 102 and 104. The robot arm 112 is controlled to automatically teach.

6 is a flowchart showing the teaching procedure of the semiconductor manufacturing equipment according to the present invention.

Referring to FIG. 6, in step S150, the substrate transfer robot 110 is moved parallel to the processing units 102 and 104 to the processing unit 104 disposed obliquely, and the plate 106 of the processing unit 104 is moved. The robot arm 112 is extended to be positioned at the top). That is, the robot arm 112 is rotated by the moving direction and by a predetermined angle θ, and is introduced into the plate 106 of the processing unit 104.

In operation S152, image data (130 of FIG. 4) of the plate 106 is obtained using the vision camera 122, and the acquired image data 130 is transmitted to the controller 124. In operation S154, the controller 124 obtains the X and Y axis coordinate values 134 of the hole 108 with respect to the central position of the plate 106 from the image data 130. In this case, the coordinate values 134 of the holes 108 are X and Y axis coordinate values of the image data 130.

As shown in FIG. 5, the robot arm 112 is moved until the origin 132 of the image data 130 falls within an error range with respect to the X and Y axis coordinate values 134 of the hole 108 in step S156. It moves left and right in the Y axis direction about the θ axis in the coordinate direction of the hole 108, and moves back and forth in the X axis direction.

In step S158, the image data 130 is acquired at the movement position of the robot arm 112, and it is determined whether the current position is within the allowable specification range (ie, the error range). For example, it is determined whether the Y axis is about 0.05 mm with respect to the X and Y axis coordinate values 134 of the hole 108.

As a result of the determination, if it is within the error range, the procedure proceeds to step S160 to obtain image data 130 for the current position of the robot arm 112, and in step S162 the X, Y axis coordinates for the hole 108. Obtain the value 134. If the determination result is not within the error range, the above-described steps 152 to S158 are repeated.

The robot arm 112 is moved in the X-axis direction by the error value of the X- and Y-axis coordinate values 134 of the hole 108 obtained in step S164 and the X-axis coordinates of the origin 132 of the current image data 130. Go to.

Subsequently, in step S166, the X and Y axis coordinate values 134 of the hole 108 and the origin 132 of the current image data 130 coincide with each other, and the robot arm 112 is processed. Recovery from the unit 104 completes the teaching setting.

In the above, the configuration and operation of the automatic teaching apparatus according to the present invention has been shown in accordance with the detailed description and drawings, which are merely described by way of example, and various changes and modifications within the scope without departing from the technical spirit of the present invention. This is possible.

1 is a perspective view showing the configuration of a semiconductor manufacturing facility for teaching a substrate transfer robot according to the prior art;

2 shows a schematic configuration of a semiconductor manufacturing facility having a processing unit arranged obliquely in accordance with the present invention;

3 is a perspective view showing the configuration of a robot arm equipped with a teaching jig using the camera shown in FIG. 2;

FIG. 4 is a view showing image data obtained by photographing the plate of the processing unit by the camera shown in FIG. 3; FIG.

FIG. 5 is a diagram for explaining coordinate transformation in the image data shown in FIG. 4; FIG. And

6 is a flowchart illustrating the teaching procedure of the automatic teaching apparatus according to the present invention.

Explanation of symbols on the main parts of the drawings

100 semiconductor manufacturing equipment 102, 104 processing unit

106: plate 108: hole

110: substrate transfer robot 112: robot arm

120: jig for teaching 122: vision camera

124 control unit 130 image data

Claims (8)

In semiconductor manufacturing equipment: A substrate transfer device having at least one robot arm on which a substrate is mounted; A plurality of processing units arranged at an angle to the movement direction of the substrate transfer device and at least one processing unit disposed in parallel with the movement direction of the substrate transfer device, wherein the plurality of substrates are transferred by the substrate transfer device; Three processing units; A jig for teaching mounted to the robot arm, and a vision camera installed on a lower surface of the jig to acquire image data of a plate of the processing unit, and the substrate transfer device for each of the processing units. An automatic teaching apparatus for setting teaching; Receiving the image data from the vision camera and setting the teaching of the robot arm to at least one processing unit disposed at an angle with respect to the moving direction of the substrate transfer device among the processing unit, the teaching of the plate from the image data Acquires the X and Y axis coordinate values for the central position, scan-moves the robot arm to match the obtained coordinate values, and the rest of the processing units arranged in parallel with the movement direction of the substrate transfer device. In setting up the teaching of the robot arm for the processing units, the coordinate arm is obtained from the image data, and the robot arm is linearly moved along the X and Y axes so as to coincide with the obtained coordinate value. To automatically teach the robot arm by storing coordinate values when coinciding with the center position of the plate. Semiconductor manufacturing equipment comprising a control unit for. The method of claim 1, The control unit; During the scan movement, the semiconductor arm is controlled to track the coordinate value by moving the robot arm left and right in the Y axis direction and simultaneously moving back and forth in the X axis direction based on the central axis with respect to the predetermined angle. equipment. The method according to claim 1 or 2, The control unit; If the robot arm moves to the coordinate value and is within an allowable error range between the center position of the plate and the robot arm, the robot arm is corrected by a deviation between the coordinate value within the error range and the coordinate value of the center position of the plate. Semiconductor manufacturing equipment, characterized in that to match the central position of the. At least one first processing unit which is disposed to be inclined at an angle with a moving direction of the substrate transfer robot among a plurality of processing units having a plate on which a semiconductor substrate is seated, and disposed in parallel with the movement direction of the substrate transfer robot A method of teaching a robot arm of the substrate transfer robot to each of the processing units in a semiconductor manufacturing facility having a remaining second processing unit, the method comprising: Move the substrate transfer robot in parallel with the second processing unit to any one of the processing units; If either one is the first processing unit, the robot arm is rotated by the predetermined angle to move above the plate of the first processing unit to obtain first image data, wherein the one is the first processing unit. If the processing unit is two, move the robotic arm above the plate of the second processing unit to obtain second image data; Obtain X and Y axis coordinate values for the central position of the plate from the first or second image data; next Scanning or linearly moving the robot arm until the X and Y axis coordinate values coincide with the origin coordinate values of the first or second image data so that the origin of the robot arm is at the center position of the plate. And a coordinate value at the time of coinciding with. The method of claim 4, wherein Scanning and moving the robot arm; Moving the robot arm in the X axis direction until the current origin coordinate value of the robot arm in motion is within an error range from the coordinate value of the center position of the plate, and in the Y axis direction based on the central axis with respect to the predetermined angle. Teaching method of a semiconductor manufacturing equipment characterized by repeating the left and right movement. The method according to claim 4 or 5, And when the current origin coordinate value of the robot arm is within the error range, teaching the robot arm by correcting a deviation between the current origin coordinate value and the X and Y axis coordinate values. Teaching method. delete delete

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