KR20070024144A - Coater unit having controller of nozzle position - Google Patents

Abstract

A coater unit having a nozzle position controller is provided to improve photoresist coating defect and to reduce process defect through a nozzle sensing unit of the nozzle position controller for detecting a position of a photoresist nozzle arm. A coater unit is provided with a nozzle position controller which detects an escape of a photoresist nozzle arm(PNA) from a home position and moves the photoresist nozzle arm to a dispense position, thereby allowing the photoresist nozzle arm to dispense a photoresist onto a wafer(W) at the home position of the dispense position. The photoresist nozzle arm holds a photoresist nozzle and includes a nozzle sensing unit for detecting the escape of the photoresist nozzle arm from the home position.

Description

Coater unit having a nozzle position control unit

1 is a schematic view showing a conventional coater unit.

FIG. 2 is a schematic view showing a state in which the photoresist nozzle arm in FIG. 1 moves to a home position to hold the photoresist nozzle; FIG.

3 is a schematic view showing a coater unit according to an embodiment of the present invention.

4 is a schematic view showing a state in which the photoresist nozzle arm in FIG. 3 moves to a home position to hold the photoresist nozzle.

FIG. 5 is a block diagram schematically illustrating a configuration of a nozzle position control unit in the coater unit of FIG. 3. FIG.

<Description of the symbols for the main parts of the drawings>

W: Wafer EBR: Edge Bead Remover

Bowl: Coater Bowl Chuck: Wafer Chuck

PDB: Photoresist Drain Bath

PN (1 ~ 4): Photoresist Nozzle

WL (1 ~ 4): Constant temperature water line 10: Nozzle sensing part

12 light emitting portion 14 light receiving portion

20: alarm signal generator 30: nozzle arm drive stop

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to process equipment for manufacturing semiconductor devices, and more particularly, to coater units of coating apparatuses used in photoresist coating processes.

In general, the process for manufacturing a semiconductor device is largely a process of manufacturing a semiconductor device, which is a core component of a semiconductor product, on a pure silicon wafer, and protecting selected good semiconductor devices from the harsh external environment and The device may include a package process for enabling the device to electrically input and output signals to and from an external device, and a test process for testing a packaged semiconductor device.

In particular, in order to selectively form a specific pattern on the wafer during such a series of processes, a photoresist is applied to a predetermined thickness over the entire surface of the wafer and then etched. By selectively etching the wafer surface, there is a preceding process of forming and developing a predetermined circuit pattern.

Then, the preceding process proceeds with subsequent steps such as implanting impurity ions into the portion where the photoresist has been removed in a specific pattern and forming a thin film having unique characteristics. Among these, the process of applying photoresist over the entire surface of the wafer includes a spin coater for rotating the wafer at high speed, and a photoresist spray nozzle for spraying the photoresist on the upper surface of the wafer being rotated at high speed. Spinner equipment is used mainly to make the photoresist uniformly applied. A photoresist must be applied to the wafer surface to selectively etch the wafer surface during the etching process. A device for applying the photoresist is a coater unit in a spinner installation. Hereinafter, the coater unit will be described with reference to the accompanying drawings.

1 is a schematic view showing a conventional coater unit.

Referring to FIG. 1, a photoresist nozzle arm (PNA) movable to the left and right of the Y axis for holding a photoresist onto a wafer W holds the photoresist nozzle and then the center C of the wafer. Move to the top of and dispense the photoresist. Then, the photoresist nozzle arm PNA again moves to the home position, which is the starting point. In addition, the wafer W loaded into the wafer chuck in the coater bowl by holding one photoresist nozzle among the photoresist nozzles PR 1 to 4 to move to a dispense position. Will be moved to). At this time, the photoresist nozzle arm PNA moves up and down to hold one of the photoresist nozzles PR 1 to 4. Generally, a spin chuck is used as the wafer chuck.

Edge Bead Removal (EBR) is a spin coating process that coats a photoresist on a wafer to remove irregularly-formed beads (also known as edges or edge geads) at the edges of the wafer after the photoresist has been coated. As a part which performs a process to make it, it is possible to rotate at a predetermined angle (phi). Reference numerals WL 1 to 4 denote constant temperature water lines, and PDB (Photoresist Drain Bath) is a photoresist drain bath where photoresist is discarded.

FIG. 2 is a schematic view showing a state in which the photoresist nozzle arm PNA in FIG. 1 moves to a home position and holds the photoresist nozzles PN 1 to 4.

Referring to FIG. 2, the photoresist nozzle arm PNA moves to a dispense position by holding one of the photoresist nozzles PN 1 to 4 to dispense the photoresist on the wafer W, and then again. Moving to the home position, the remaining photoresist is discarded into the photoresist drain bath (PDB).

As described above, in the conventional coater unit, since the photoresist nozzle arm does not move to the home position when the photoresist nozzle moves to hold the photoresist nozzle at the home position, the wafer is held after the photoresist nozzle is moved to the dispense position. When dispensing a photoresist on the problem there is a problem that the photoresist is not dispensed in the center of the wafer. As a result, photoresist coating defects may be caused, resulting in frequent process defects.

Accordingly, an object of the present invention is to provide a coater unit having a nozzle position control unit for improving the problem of not moving to the home position when the photoresist nozzle arm moves to hold the photoresist nozzle in the home position as described above. Is in.

Another object of the present invention is a coater unit having a nozzle position control unit for improving the problem that the photoresist is not dispensed at the center of the wafer when the photoresist is dispensed on the wafer after holding the photoresist nozzle to move to the dispense position. In providing.

Still another object of the present invention is to provide a coater unit having a nozzle position control unit for reducing or minimizing process defects due to photoresist coating defects.

In order to achieve the above objects, a coater unit for coating a photoresist on a wafer according to an aspect of the present invention is provided at a home position when the photoresist nozzle arm moves to a home position to hold the photoresist nozzle. And a nozzle position control unit configured to detect the deviation and move the photoresist nozzle arm to the dispense position to dispense the photoresist on the wafer at the correct position of the dispense position.

Here, the nozzle position control unit may include a nozzle sensing unit for detecting whether the photoresist nozzle arm is separated from the home position.

The nozzle position control unit may include an alarm signal generation unit for generating an alarm signal when the photoresist nozzle arm is separated from the home position by receiving a detection result from the nozzle sensing unit.

The nozzle position control unit may include a nozzle arm driving stop unit for stopping the operation of the photoresist nozzle arm when the photoresist nozzle arm is separated from the home position.

The nozzle sensing unit may include a light emitting unit for irradiating light; And a light receiving unit installed at a position corresponding to the light emitting unit when the photoresist nozzle arm is positioned at the home position to receive the light emitted from the light emitting unit. The light emitting part may be installed in the photoresist nozzle arm, and the light receiving part may be installed in a photo drain bath for dispensing the photoresist.

The nozzle sensing unit may include a magnetic sensor.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The descriptions in the various embodiments are only shown and limited by way of example and without intention other than the intention to help those of ordinary skill in the art to more thoroughly understand the present invention, and thus the scope of the present invention. It should not be used as a limitation.

3 is a schematic view showing a coater unit according to an embodiment of the present invention.

Referring to FIG. 3, a wafer W, an edge bead remover EBR, a coater bowl, a wafer chuck, a photoresist nozzle arm PNA, and a photoresist nozzle PN 1 to 4 , Constant temperature water line WL 1-4 and photoresist drain bath PDB are shown. Since the above-described parts of the coater unit have already been described, duplicated descriptions will be omitted.

FIG. 4 is a schematic diagram illustrating a state in which the photoresist nozzle arm in FIG. 3 moves to a home position to hold the photoresist nozzle, and FIG. 5 is a block diagram schematically illustrating a configuration of a nozzle position control unit in the coater unit of FIG. 3. to be.

First, referring to FIG. 4, according to the present invention, a coater unit for coating a photoresist on a wafer (W in FIG. 3) has a photoresist nozzle arm PNA moved to a home position so that a photoresist nozzle PN (1) may be used. 4)), the photoresist nozzle arm is moved to the dispensing position by detecting the deviation from the home position of the home position, and the wafer W is positioned at the dispensing position (center C of the wafer). And a nozzle position control unit for dispensing the photoresist on the substrate.

That is, when the photoresist nozzle arm PNA moves to the home position to hold the photoresist nozzles PN 1 to 4, the coater unit is not placed in the correct position of the home position capable of holding the nozzle. Problems such as collisions with outer walls or other parts of the system will occur. At this time, the nozzle position control unit (refer to FIG. 5) detects that the photoresist nozzle arm is separated from the home position.

The nozzle position control unit includes a nozzle sensing unit 10, an alarm signal generator 20, and a nozzle arm driving stop unit 30.

The nozzle sensing unit 10 is a part for detecting whether the photoresist nozzle arm PNA is separated from the home position. Accordingly, the nozzle sensing unit 10 may include various types of sensors to detect whether the photoresist nozzle arm PNA is separated from the home position. For example, the nozzle sensing unit 10 may be an optical sensor including a light emitting unit 12 and a light receiving unit 14. The light emitting unit 12 is mounted on the nozzle, and the light receiving unit 14 is mounted on the photoresist drain bath PDB so that the photoresist nozzle arm PNA is always in a constant position (the home position). ) Is moved to allow the photoresist nozzles PN 1 to 4 to be sensed. Alternatively, the nozzle sensing unit 10 may be a magnetic sensor. That is, by using the magnetic device, when the photoresist nozzle arm PNA is mounted on the photoresist drain bath PDB and reaches a predetermined position (the correct position of the home position), it may be detected. .

The alarm signal generator 20 receives a detection result from the nozzle sensing unit 10 and generates an alarm signal when the photoresist nozzle arm PNA is separated from the home position. The alarm signal may be an alarm sound or an alarm light.

The nozzle arm driving stop unit 30 is a part for stopping the operation of the photoresist nozzle arm PNA when the photoresist nozzle arm PNA is separated from the home position.

As described above, the present invention provides a coater unit having a nozzle arm controller, whereby the photoresist nozzle arm holds the photoresist nozzle to move to the center of the wafer, and then dispenses or coats the photoresist on the wafer, and then starts again. When moving to the home position, only the up / down operation is performed at the home position. When the next wafer is loaded into the coater unit and held by moving the photoresist nozzle to dispense the photoresist again, the photo is placed in the center of the wafer. Since the resist is not dispensed, it is possible to improve a problem in which photoresist coating defects and process defects are generated.

Coater unit according to an embodiment of the present invention is not limited to the above embodiment, it can be variously designed and applied within the scope without departing from the basic principles of the present invention having a common knowledge in the art It will be obvious to one.

As described above, the present invention has the effect of improving the problem of not moving to the right position when the photoresist nozzle arm moves to hold the photoresist nozzle in the home position by providing the coater unit with the nozzle position control unit. .

In addition, the present invention provides a coater unit having a nozzle position control unit to hold the photoresist nozzle to move to the dispense position, when dispensing the photoresist on the wafer, the problem that the photoresist is not dispensed in the center of the wafer Has the effect of improving. Thus, the present invention has the effect of reducing or minimizing process defects due to poor photoresist coating.

Claims (7)

In a coater unit for applying photoresist on a semiconductor wafer: Detecting that the photoresist nozzle arm for holding and moving the photoresist nozzle is deviated from the home position, the photoresist nozzle arm moves to the dispense position to deposit the photoresist on the wafer at the dispense position. And a nozzle position control unit for dispensing. The method of claim 1, And the nozzle position control unit includes a nozzle sensing unit for detecting whether the photoresist nozzle arm is separated from the home position. The method of claim 2, The nozzle position controller may include an alarm signal generator configured to receive a detection result from the nozzle sensing unit and to generate an alarm signal when the photoresist nozzle arm is separated from the home position. . The method of claim 3, And the nozzle position control unit includes a nozzle arm driving stop unit for stopping the operation of the photoresist nozzle arm when the photoresist nozzle arm is separated from the home position. The method of claim 2, wherein the nozzle sensing unit, A light emitting unit for irradiating light; And And a photo sensor having a light receiving unit installed at a position corresponding to the light emitting unit when the photoresist nozzle arm is in a correct position of the home position in order to receive the light emitted from the light emitting unit. The method of claim 5, And the light emitting part is installed in the photoresist nozzle arm, and the light receiving part is installed in a photo drain bath for dispensing the photoresist. The method of claim 2, And the nozzle sensing unit has a magnetic sensor.

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