JP5484136B2 - Substrate processing equipment - Google Patents

Description

  The present invention relates to a substrate processing apparatus that performs a predetermined process such as a drying process on a glass substrate (hereinafter simply referred to as a substrate) for a semiconductor wafer or a liquid crystal display device, and more particularly, a substrate from a processing liquid such as pure water. The present invention relates to a technique for performing a drying process on a substrate while pulling up.

  Conventionally, this type of substrate processing apparatus is configured to support a processing tank for storing a processing liquid such as pure water and a plurality of wafers and the like and to be moved up and down over the inside of the processing tank and above the processing tank. A substrate processing apparatus provided with a lifter and a nozzle for supplying dry air (drying gas) from one side to the other side in the horizontal direction provided near the liquid surface of the processing tank (for example, Patent Document 1). , 2).

  In the substrate processing apparatus configured as described above, for example, the lifter is lowered in a processing tank storing pure water so that the substrate is immersed in pure water, and then hydrofluoric acid (HF) is mixed in the processing tank. Thus, a processing liquid for etching is generated. After the treatment with hydrofluoric acid for a predetermined time, pure water is supplied to the treatment tank to replace the treatment liquid containing hydrofluoric acid with pure water. After rinsing with pure water for a predetermined time, the lifter is raised while supplying dry air from the nozzle. Thereby, the substrate pulled up from the liquid surface of the processing liquid by the lifter is dried by dry air. Since the dry air supply device requires a long time to generate dry air with a low dew point, it is generally operated at all times. For this reason, dry air is also supplied when a process using a processing solution for etching is performed.

JP 2008-205360 A JP 2008-78190 A

  However, the conventional substrate processing apparatus having such a configuration has the following problems. In other words, in the conventional substrate processing apparatus, the dry air with a low dew point is used to achieve a rapid drying process on the substrate. However, in the configuration of the conventional substrate processing apparatus, the dry air generated by the dry air generator is When the substrate is supplied from the supply unit to the chamber through the supply pipe and the drying process for the substrate is completed in the chamber, the substrate processing apparatus is completely exhausted through the discharge unit. Although the dry air drying apparatus itself has already demonstrated COO performance, the used dry air is discarded as it is from the discharge section, which causes a problem that the dry air is wasted.

  This invention is made | formed in view of such a situation, and it aims at providing the substrate processing apparatus which can use dry gas efficiently.

In order to solve the above-described problem, the invention described in claim 1 is a substrate processing apparatus that performs a cleaning process and a drying process on a substrate. A holding mechanism that moves to a processing position in the processing tank and an upper position of the processing tank in a held state, and an upper position on one end side of the processing tank, and supplies dry gas to the upper position of the processing tank. A supply unit, an upper position on the other end side of the processing tank, disposed at a position facing the supply unit, and a discharge unit for discharging the dry gas supplied to the upper position of the processing tank, A supply path for supplying dry gas to the supply unit, a discharge path for discharging dry gas from the discharge unit, and a dry gas that is connected in communication between the supply path and the discharge path and flows to the discharge path. Return to the supply path A circulation path, wherein the discharge of the drying gas from the discharge path and the switching mechanism for switching the circulation of the drying gas into the circulation path, a fan provided in the circulation path, dried before being supplied from the supply unit A first dew point meter that measures the dew point of the gas, a second dew point meter that measures the dew point of the dry gas after being discharged from the discharge unit, the first dew point meter and the second dew point meter. When the measured dew point becomes a predetermined temperature or less, the switching mechanism is controlled to switch from the discharge of the dry gas to the circulation of the dry gas to the circulation path, and the fan is dried to the circulation path by the fan. And a control means for supplying a gas .

  According to the substrate processing apparatus described in the present invention, before performing the drying process on the substrate, the switching mechanism switches from the discharge of the dry gas from the discharge path to the circulation of the dry gas to the circulation path. The dry gas can be used while being circulated. As a result, the dry gas can be used efficiently.

It is a figure which shows schematic structure of the substrate processing apparatus which concerns on embodiment of this invention. It is a block diagram of a dry air supply device. It is a block diagram of the electric system of the substrate processing apparatus which concerns on embodiment of this invention. It is a flowchart which shows the first half part of the processing operation of a substrate processing apparatus. It is a flowchart which shows the latter half part of the processing operation of a substrate processing apparatus.

  Hereinafter, embodiments of a substrate processing apparatus of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a schematic configuration of a substrate processing apparatus according to an embodiment of the present invention.

The substrate processing apparatus includes a processing tank 1 for storing a processing solution such as a chemical solution or pure water. The processing tank 1 stores a processing liquid and can accommodate a plurality of substrates W in an upright posture. At the bottom of the processing tank 1, there is a pair of ejection pipes 7 having a long axis along a direction (paper surface direction) in which a plurality of substrates W are aligned and for supplying a processing liquid into the processing tank 1. It is arranged. One end side of the supply pipe 8 is connected to the right ejection pipe 7, and the other end side of the supply pipe 8 is connected to a processing liquid supply source (not shown). One end side of a supply pipe 9 is connected to the left ejection pipe 7, and the other end side of the supply pipe 9 is connected to a processing liquid supply source (not shown). In the pair of ejection pipes 7, a plurality of ejection holes (not shown) are formed along the long axis direction in order to supply the treatment liquid into the treatment tank 1. The supply pipes 8 and 9 use a treatment liquid such as a chemical solution such as hydrofluoric acid (HF) or a mixed solution (SPM) of sulfuric acid / hydrogen peroxide solution (H ₂ SO ₄ / H ₂ O ₂ ), pure water, or the like. To the inside of the treatment tank 1. Flow control valves 10 and 11 are attached to the supply pipes 8 and 9, respectively, and the flow rate of the processing liquid supplied from the pair of ejection pipes 7 to the processing tank 1 is adjusted by these.

  The processing tank 1 is surrounded by a chamber 12. The chamber 12 includes an upper cover 13 that can be freely opened and closed. The lifter 15 that supports the plurality of substrates W in a standing posture includes a “standby position” that is above the chamber 12, a “processing position” that is inside the processing tank 1, and an interior of the chamber 12 that is above the processing tank 1. It can move over the “drying position”. The lifter 15 includes three support members 16 at the bottom for supporting a plurality of substrates W.

  A detection sensor 14 that detects the passage of the lifter 15 that supports a plurality of substrates W is provided at a “standby position” above the chamber 12. This detection sensor 14 detects the lifter 15 before being carried into the chamber 12.

  A discharge port 17 is formed at the bottom of the processing tank 1. A QDR valve 19 is attached to the discharge port 17. When the processing liquid in the processing tank 1 is discharged through the discharge port 17, the processing liquid is once discharged to the bottom of the chamber 12. A drain valve 21 is attached to the bottom of the chamber 12. When the drain valve 21 is opened, the processing liquid once stored in the chamber 12 is discharged to the outside of the chamber. Further, the processing liquid supplied from the ejection pipe 7 and overflowing from the processing tank 1 and discharged into the chamber 12 is also discharged outside through the drain valve 21 in the same manner.

  A supply unit 23 for supplying dry air, which is a dry gas, from the side of the plurality of substrates W supported by the lifter 15 is disposed on the side of the upper edge of the processing tank 1 in the chamber 12. A discharge unit 25 for discharging the dry air from the chamber 12 is disposed at a position facing the supply unit 23 with the processing tank 1 interposed therebetween. The supply unit 23 includes an injection port 27 that ejects dry air so as to open near the liquid level of the processing liquid stored in the processing tank 1, and the discharge unit 25 discharges the dry air to the outside of the chamber 12. A discharge port 29 is provided on the processing tank 1 side.

  The supply unit 23 is connected to the other end of a supply pipe 33 having one end connected to the dry air supply device 31 in communication. A detailed description of the dry air supply device 31 will be described later.

  One end of a discharge pipe 39 is connected to the discharge unit 25 in communication. A blower (not shown) is connected to the other end side of the discharge pipe 39. In the middle of the discharge pipe 39, a second dew point meter 41 and an on-off valve 43 are provided in this order from the upstream side. By controlling the opening / closing of the on / off valve 43, the discharge / stop (circulation) of the dry air from the chamber 12 is switched. When the blower operates with the open / close valve 43 open, the dry air in the chamber 12 is discharged to the outside of the substrate processing apparatus through the discharge port 29 and the discharge pipe 39 of the discharge unit 25.

  This substrate processing apparatus is provided with a circulation pipe 45 having one end connected to the dry air supply device 31 and having the other end connected to a position between the second dew point meter 41 and the on-off valve 43 in the discharge pipe 39. ing. In the middle of the circulation pipe 45, an upstream side open / close valve 47, a fan 49, and a downstream side open / close valve 51 are provided in this order from the upstream side. Supply / stop of the dry air to the circulation pipe 45 is switched by controlling the opening / closing of the upstream opening / closing valve 47 and the downstream opening / closing valve 51. The on-off valve 43 and the upstream-side on-off valve 47 correspond to the switching mechanism in the present invention.

  Next, the dry air supply device will be described. FIG. 2 is a block diagram of the dry air supply device.

  The dry air supply device 31 is provided with a supply pipe 53 connected to one end side of the supply pipe 33. An air supply source (not shown) is connected to the upstream side of the supply pipe 53. The supply pipe 53 is provided with a fan 55, an on-off valve 57, a dry air generation mechanism 70, and a first dew point meter 59 for flowing air supplied from an air supply source to the downstream chamber 12 in order from the upstream side. It has been.

  The other end side of the circulation pipe 45 is connected to a position between the on-off valve 57 of the supply pipe 53 and the dry air generation mechanism 70. The dry air supplied from the circulation pipe 45 flows to the dry air generation mechanism 70 and the first dew point meter 59 side when supplied to the supply pipe 53 with the on-off valve 57 closed.

  One end of the discharge pipe 60 is connected to a position upstream of the position where the fan 55 of the supply pipe 53 is provided. The exhaust pipe 60 is provided with a fan 62 for exhausting air supplied from an air supply source from the dry air supply device 31, a heater 64 for heating air, and a dry air generating mechanism 70 in this order from the upstream side.

  Next, the dry air generation mechanism 70 will be described.

  The dry air generation mechanism 70 includes a cylindrical zeolite 71, a shaft core member 72, and a motor 73. One end side of the shaft core member 72 is connected to a rotation shaft (not shown) of the motor 73. A zeolite 71 is attached to the other end side of the shaft core member 72.

  The zeolite 71 has a structure having a plurality of micropores, and adsorbs water molecules. The zeolite 71 is positioned between the upstream supply pipe 53 and the downstream supply pipe 53 and the upstream discharge pipe 60 and the downstream. It arrange | positions in the position between the discharge piping 60 of the side. Air before dehumidification (temperature 25 ° C., humidity 45%) supplied from the air supply source to the upstream supply pipe 53 in the open state of the on-off valve 57 is supplied to the zeolite 71. When the air passes through the zeolite 71, dry air is generated, and the moisture contained in the air is absorbed by the zeolite 71.

  At this time, since the motor 73 is driven, the zeolite 71 rotates in one direction. Along with the rotation of the zeolite 71, the portion containing the moisture of the zeolite 71 located between the upstream supply pipe 53 and the downstream supply pipe 53 is connected to the upstream discharge pipe 60 and the downstream discharge pipe. Move to a position between 60.

  On the other hand, the air flowing from the supply pipe 53 to the discharge pipe 60 is heated by the heater 64 to become high-temperature air, and the moisture of the zeolite 71 located at a position between the upstream discharge pipe 60 and the downstream discharge pipe 60. Supplied to the part containing The portion of the zeolite 71 containing moisture is dried by this high-temperature air. Thereby, the zeolite 71 can be used again for generating dry air.

FIG. 3 is a block diagram of the electrical system of this substrate processing apparatus. As shown in FIG. 3, the lifter 15 moves up and down as described above, opens and closes the QDR valve 19 and the drain valve 21, the flow control valves 10 and 11, the on-off valves 43, 47, 51, 57, and the detection sensor 14. The first dew point meter 59, the second dew point meter 41, the fans 49, 55, 62, the heater 64, and the motor 73 are centrally controlled by the control unit 80 corresponding to the control means in the present invention. In particular, the flow control valves 10 and 11, the detection sensor 14, and the on-off valves 43, 47, 51, and 57 are operated by the control unit 80 as described below.

  Next, the operation of the substrate processing apparatus having the above-described configuration will be described with reference to FIGS. FIG. 4 is a flowchart showing the first half of the processing operation of the substrate processing apparatus, and FIG. 5 is a flowchart showing the second half of the processing operation of the substrate processing apparatus.

<Before cleaning>
First, as an initial state, before the lifter 15 supporting a plurality of substrates W is carried into the chamber 12, the on / off valves 43, 47, 51, 57 are closed by the control from the control unit 80. is there. The detection sensor 14 detects the lifter 15 holding a plurality of substrates W in “standby position” (step S1). When the detection sensor 14 detects the lifter 15, the upper cover 13 is opened, and the substrate W can be carried into the chamber 12 (step S2).

  Next, the lifter 15 supporting the plurality of substrates W is carried into the chamber 12 (step S3). The lifter 15 that supports the plurality of substrates W moves from the “standby position” to the “drying position” and from the “drying position” to the “processing position”, and the plurality of substrates W are processed in the processing tank 1. It is immersed in the liquid, and the carry-in of the lifter 15 is completed (step S4). When the carry-in of the lifter 15 into the processing tank 1 is completed, the upper cover 13 is closed (step S5).

<During washing process>
Next, the control unit 80 sets the flow rate control valves 10 and 11 to the same flow rate, opens them, and causes the pair of jet pipes 7 to supply the chemical solution as the processing liquid into the processing tank 1 at the same flow rate. Then, the chemical solution is supplied from the pair of ejection pipes 7 at both ends of the bottom of the processing tank 1, and moves upward at the center of the bottom, and is divided into left and right near the liquid surface and overflows from the processing tank 1. By maintaining this state for a predetermined time, the substrate W is processed with a chemical solution (step S6).

  Next, the control unit 80 supplies pure water as treatment liquid from the pair of ejection pipes 7 at the same flow rate into the treatment tank 1. Then, pure water is supplied from a pair of jet pipes 7 at both ends of the bottom of the processing tank 1, upwards at the center of the bottom, and divided into left and right near the liquid level and overflows from the processing tank 1. By maintaining this state for a predetermined time, a rinsing process is performed on the substrate W (step S7).

  During the rinsing process, when the control unit 80 starts driving the fan 55 and opens the on-off valves 57 and 43 from the closed state to the open state, the upper portion of the processing tank 1 receives dry air from the injection port 27 of the supply unit 23. It is supplied and is discharged from the discharge port 29 of the discharge unit 25 (step S8). It is determined whether a predetermined time has elapsed since the start of the rinsing process (step S9). If the predetermined time has elapsed, the rinsing process is completed, and the rinsing process is shifted to the drying process.

<Drying process>
The controller 80 sets the flow rate of the flow control valve 11 to zero (step S10). Thereby, the supply of pure water is stopped from the left jet pipe 7 and pure water is supplied only from the right jet pipe 7. Therefore, after deionized water goes from the bottom right side of the processing tank 1 to the left ejection pipe 7 side along the bottom, it rises along the side wall of the processing tank 1, and the vicinity of the liquid level toward the discharge unit 25 side. After flowing, it overflows from the upper edge of the processing tank 1 and is discharged.

  At this time, the dew point of the dry air supplied from the injection port 27 of the supply part 23 is confirmed. That is, the first dew point meter 59 is −95 ° C. or less for the dew point of the dry air before being supplied from the supply unit 23, and the second dew point meter 41 is −30 ° C. for the dew point after being discharged from the discharge unit 25. It is determined whether or not the following is true (step S11). If the first dew point meter 59 and the second dew point meter 41 satisfy the condition of step S11, the open / close valve 43 is opened and closed, the open / close valve 47 is closed and opened, and the fan 49 is driven. And circulation of dry air to the circulation pipe 45 is started (step S12).

When enough dry air is fed into the circulation pipe 45 by the fan 49, the on-off valve 5 7 from the open-closed state, the opening and closing valve 51 as well as from the closed to the open state, the fan 55 is stopped, circulation of dry air The circulation to the pipe 45 is completed (step S13).

  Next, the lifting of the lifter 15 supporting the plurality of substrates W after the rinsing process from the pure water is started (step S14). As the lifter 15 is lifted, dry air is supplied to the substrate W that is sequentially exposed from the liquid surface of the pure water, and the substrate W is dried (step S15). At this time, when the lifter 15 is lifted from the processing tank 1, the three support members 16 that abut and support the plurality of substrates W are arranged in the air passage formed between the supply unit 23 and the discharge unit 25. Position alignment is performed, and the lifter 15 is once stopped (step S16).

  In this way, the substrate W is dried. However, since the supply direction of the dry air and the flow of pure water in the vicinity of the liquid surface coincide with each other, the flow of pure water hardly causes stagnation and is peeled off from the substrate W during cleaning. Thus, particles drifting in the pure water and particles originally existing in the pure water in the treatment tank 1 are efficiently discharged. As a result, it is possible to prevent particles from adhering to the substrate W to be pulled up, and the substrate W can be processed with high cleanliness. In addition, since the central portion of the liquid surface does not rise and it is possible to prevent the air surface from being rippled by dry air, it is possible to prevent the droplets from adhering to the substrate W being pulled up and to dry the substrate W. Defects can be prevented.

  When the drying process is completed, the upper cover 13 is opened, and the substrate W can be taken out from the chamber 12 (step S17). At this time, the fan 49 of the circulation pipe 45 is stopped, the on-off valve 47 and the on-off valve 51 are changed from the open state to the closed state, and the circulation of the dry air to the circulation pipe 45 is finished (step S18). Thereafter, the lifter 15 is unloaded from the chamber 12 (step S19).

  Thus, a series of processing operations of the substrate processing apparatus including the chemical processing, rinsing processing, and drying processing for the wafer W is completed.

  According to the above-described embodiment, before the substrate W is dried, if the first dew point meter 59 and the second dew point meter 41 satisfy the condition of step S11, the on / off valve 43 is opened to the closed state. 47 is changed from closed to open, and circulation of dry air to the circulation pipe 45 is started. When sufficient dry air is sent into the circulation pipe 45 by the fan 49, the on-off valve 57 is opened and closed. While the valve 51 is changed from the closed state to the open state, the fan 55 is stopped and the circulation of the dry air to the circulation pipe 45 is completed. As a result, the dry air can be used while being circulated through the circulation pipe 45. As a result, there is a remarkable effect that the dry air can be used efficiently.

  Further, according to the above-described embodiment, the circulation of the dry air to the circulation pipe 45 is controlled by the two dew point meters of the first dew point meter 59 and the second dew point meter 41, so that the circulation is performed at an accurate and correct time. Can start.

  The present invention is not limited to the above embodiment, and can be modified as follows.

  For example, in the above-described embodiment, the processing tank 1 is configured as a single tank, but is a multi-tank processing tank including an inner tank and an outer tank that collects a processing liquid overflowing from the inner tank. Also good.

In the above-described embodiment, dry air is supplied from the supply unit 23. However, instead of this, dry nitrogen (N ₂ ) or other dry gas may be supplied.

DESCRIPTION OF SYMBOLS 1 Processing tank 12 Chamber 15 Lifter 23 Supply part 25 Discharge part 27 Injection port 29 Discharge port 31 Dry air supply device 33 Supply pipe 39 Discharge pipe 41 2nd dew point meter 42 Open / close valve 45 Circulation pipe 47 Open / close valve 49 Fan 51 Open / close valve 57 On-off valve 59 First dew point meter

Claims (1)

In a substrate processing apparatus that performs a cleaning process and a drying process on a substrate,
A treatment tank for storing a treatment liquid for immersing the substrate;
In a state where the substrate is held, a holding mechanism that moves to a processing position in the processing tank and a position above the processing tank;
A supply unit that is disposed at an upper position on one end side of the processing tank and supplies a dry gas to an upper position of the processing tank;
An upper position on the other end side of the processing tank, disposed at a position facing the supply section, and a discharge section for discharging the dry gas supplied to the upper position of the processing tank;
A supply path for supplying dry gas to the supply unit;
A discharge path for discharging dry gas from the discharge unit;
A circulation path that is connected in communication between the supply path and the discharge path and returns the dry gas that has flowed to the discharge path to the supply path;
A switching mechanism for switching between discharge of dry gas from the discharge path and circulation of dry gas to the circulation path;
A fan provided in the circulation path;
A first dew point meter for measuring a dew point of the dry gas before being supplied from the supply unit;
A second dew point meter for measuring the dew point of the dry gas after being discharged from the discharge unit;
When the dew points measured by the first dew point meter and the second dew point meter are below a predetermined temperature, the switching mechanism is controlled to discharge dry gas from the dry gas to the circulation path. Control means for switching to circulation and supplying dry gas to the circulation path by the fan;
A substrate processing apparatus comprising:

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