JP2005197431A - Load port device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide only a kind of load port device which is mounted on a plurality of kinds of semiconductor manufacturing apparatus. <P>SOLUTION: On a circumferential edge of a carrier base 9 forming a load port device A, a first positioning member P<SB>1</SB>(each positioning pin 15) is mounted for setting a first wafer carrier C<SB>1</SB>through the positioning, and a second positioning member P<SB>2</SB>(each corner part positioning plate 23 and each groove forming plate 24) is mounted on the internal part of the first positioning member P<SB>1</SB>for setting a second wafer carrier C<SB>2</SB>through the positioning. When one wafer carriers C<SB>1</SB>, C<SB>2</SB>are set, these are freed from interference with the positioning members P<SB>1</SB>, P<SB>2</SB>for positioning the other wafer carriers C<SB>1</SB>, C<SB>2</SB>. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a load port apparatus for installing a wafer carrier that is detachably attached to a semiconductor manufacturing apparatus and stores a large number of wafers.

  A wafer processing apparatus, which is an example of a semiconductor manufacturing apparatus, is an apparatus for performing predetermined processing on a wafer, and a load port apparatus for installing a wafer carrier is mounted (see FIG. 1). Various technologies have been disclosed for this load port device (see, for example, Patent Document 1). The operation of introducing the wafer stored in the wafer carrier into the wafer processing apparatus is performed as follows. A wafer transfer hand of a robot built in the wafer process apparatus enters the wafer carrier, and one wafer is taken out. The wafer is transferred into the wafer processing apparatus by the wafer transfer hand and subjected to predetermined processing. The wafer subjected to the predetermined processing is again stored in the wafer carrier by the wafer transfer hand.

  The wafers having the same size (same outer diameter) are accommodated in a wafer carrier in multiple stages. The wafers have various sizes (outer diameters) (for example, 200 mm, 300 mm, etc.). A dedicated wafer carrier for accommodating these wafers is used corresponding to the size of the wafer carrier. Also, dedicated wafer process apparatuses and load port apparatuses are used corresponding to the size of the wafer.

Here, the shape of each wafer carrier and the structure for installation on the carrier base are standardized as industry standards. The wafer carrier will be described with reference to FIGS. 3 and 4 of the present case. As shown in FIG. 3, three pedestals 16 are fixed in a radial manner on the bottom surface of a 300 mm wafer carrier C ₁ . When the wafer carrier C ₁ is installed on the carrier base 9 of the load port device A for 300 mm, the three positioning pins 15 (first positioning members P ₁ ) provided on the carrier base 9 Each positioning pin groove portion 16 a provided in the pedestal portion 16 enters. Accordingly, the wafer carrier C ₁ is positioned and installed on the carrier base 9.

In the case of the 200 mm wafer carrier C ₂ , as shown in FIG. 4, a pair of bottom ribs 20 provided on the bottom surface of the main body 19 and a pair of back ribs 21 provided on the back surface. Each corner portion 21a formed in the connecting portion of each is brought into contact with each corner portion positioning plate 23 (second positioning member P ₂ ) fixed to the carrier base 9 and between the pair of bottom surface ribs 20. The positioning bar 22 projecting into the groove enters the groove 25 formed between the groove forming plates 24 (second positioning members P ₂ ) fixed to the carrier base 9. Thereby, the wafer carrier C ₂ is positioned and installed on the carrier base 9.

The load port apparatus A is detachably attached to the wafer process apparatus. Conventionally, when a load port device for 200 mm breaks down, an adapter is attached to the load port device for 300 mm so that it can be used as a load port device for 200 mm. However, it is troublesome to install the adapter one by one. Moreover, in the opposite case, that is, when the load port device for 300 mm breaks down, it is impossible to mount the load port device for 200 mm. As a result, it is necessary to deploy many types of load port devices.
JP 2003-249535 A

  In view of the above-described problems, an object of the present invention is to allow only one type of load port device to be mounted on a plurality of types of semiconductor manufacturing apparatuses.

  The invention of claim 1 for solving the above-described problems includes an apparatus main body detachably attached to a semiconductor manufacturing apparatus, a carrier table for installing a wafer carrier for storing a wafer to be processed by the semiconductor manufacturing apparatus, and Each of the first and second wafers having different sizes is mounted on the carrier table. The load table is mounted on a semiconductor manufacturing apparatus having the same mounting surface configuration on which the apparatus main body is mounted. First and second positioning members for positioning the carrier and setting them at overlapping positions are provided, and each of the first and second positioning members is positioned with one wafer carrier positioned and installed on the other wafer. The arrangement structure is such that the positioning member of the carrier does not interfere.

  With the configuration described above, the first and second wafer carriers having different sizes can be installed as they are on the carrier table of the load port apparatus according to the present invention. At this time, the positioning member of the other wafer carrier does not interfere with one wafer carrier installed. For this reason, if the configuration of the mounting surface of the load port device in the semiconductor manufacturing apparatus is the same, the load port device can be used regardless of the size of the installed wafer carrier, and only one type of load port device is required. Further, since wafer carriers of different sizes can be installed as they are, there is no need to attach an adapter or the like as in the prior art. As a result, even if a load port device attached to any one of the semiconductor manufacturing apparatuses breaks down, the load port apparatus attached to another semiconductor manufacturing apparatus can be easily detached and attached.

  According to a second aspect of the present invention, on the premise of the first aspect of the invention, the first positioning member for positioning the larger first wafer carrier is a plurality of positioning pins provided outside the installation area of the second wafer carrier. In addition, the second positioning member is configured by a plurality of positioning plates having a height that does not interfere with the bottom surface of the first positioning member when the first wafer carrier is installed. Therefore, each positioning member for positioning one wafer carrier can be easily attached to the carrier table without interfering with the other wafer carrier in the installed state.

  According to a third aspect of the invention, on the premise of the second aspect of the invention, the carrier table is configured to clamp the first wafer carrier in order to prevent the first wafer carrier from being removed during operation of the load port device. The clamp device constituting the clamp device is arranged so as to be retractable from the second wafer carrier in the installed state. In this invention, the 1st wafer carrier installed in the carrier table is clamped by the clamp device so that separation from the carrier table is impossible. For this reason, it is possible to prevent a problem that an operator mistakenly removes the first wafer carrier during operation of the load port device.

  According to a fourth aspect of the invention, on the premise of the second or third aspect of the invention, the carrier table covers the second wafer carrier so as to prevent the second wafer carrier from being removed during the operation of the load port device. The cover member is attached so as to avoid interference with the first wafer carrier in the installed state. In this invention, the 2nd wafer carrier installed in the carrier table is covered with a cover member. For this reason, the malfunction that an operator accidentally removes the 2nd wafer carrier during operation of a load port device can be prevented.

  A load port apparatus according to the present invention includes an apparatus main body that is detachably mounted on a semiconductor manufacturing apparatus, and a carrier table for installing a wafer carrier that stores a wafer to be processed by the semiconductor manufacturing apparatus. A load port apparatus to be mounted on a semiconductor manufacturing apparatus having the same mounting surface configuration on which a main body is mounted, wherein first and second wafer carriers having different sizes are positioned on the carrier table. The first and second positioning members are installed at overlapping positions, and the first and second positioning members are positioned in a state where one wafer carrier is positioned, and the positioning member of the other wafer carrier is It is characterized by an arrangement structure that does not interfere. For this reason, if the configuration of the mounting surface of the load port device in the semiconductor manufacturing apparatus is the same, the load port device can be used regardless of the size of the installed wafer carrier, and only one type of load port device is required. Further, since wafer carriers of different sizes can be installed as they are, there is no need to attach an adapter or the like as in the prior art. As a result, even if a load port device attached to any one of the semiconductor manufacturing apparatuses breaks down, the load port apparatus attached to another semiconductor manufacturing apparatus can be easily detached and attached.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in more detail with reference to the best examples of the present invention. 1 is a perspective view of a load port apparatus A according to the present invention, FIG. 2 is a side view of the same, FIG. 3 is a perspective view of a state in which a first wafer carrier C ₁ is installed on a carrier base 9, and FIG. perspective of the state diagram of installing the second wafer carrier C _2, FIG. 5 is a side view, FIG. 6 is a plan view of the clamping device D and the base mobile device E, 7 is a side view of the base mobile device E of the clamping device D .

First, the overall configuration of the load port apparatus A will be described. As shown in FIGS. 1 and 2, the load port apparatus A is an apparatus main body 1 mounted on a mounting surface F provided at a predetermined position of wafer process apparatuses B ₁ and B ₂ which are examples of semiconductor manufacturing apparatuses. A lid attaching / detaching device (not shown) disposed inside the apparatus main body 1 (on the side of the wafer process apparatuses B ₁ and B ₂ ), and a table main body 2 protruding from the apparatus main body 1. And a table device T. The wafer process apparatus B ₁ is an apparatus for processing a wafer W ₁ having an outer diameter of 300 mm (see FIG. 3), and the wafer process apparatus B ₂ is a wafer W ₂ having an outer diameter of 200 mm (see FIG. 4). ). Hereinafter, the wafer carrier in which the wafer W ₁ having an outer diameter of 300 mm is stored is referred to as “first wafer carrier C ₁ ”, and the wafer carrier in which the wafer W ₂ having an outer diameter of 200 mm is stored is referred to as “second wafer. “Carrier C ₂ ”. It will be appreciated that, the larger of the first wafer carrier C _1. The configuration of the mounting surface F of the load port apparatus A in each of the wafer process apparatuses B ₁ and B ₂ is the same.

The apparatus main body 1 constituting the load port apparatus A is a plate having a predetermined thickness, and a wafer transfer window 3 for transferring the wafer W is opened at an upper part thereof. In addition, six bolt holes 4 are provided at a predetermined interval in the peripheral portion of the apparatus body 1, and a pin hole 5 is provided in a substantially central portion in the width direction at the upper end portion thereof. . In the load port apparatus A, the apparatus main body 1 is mounted on the mounting surface F of the wafer process apparatuses B ₁ and B _{2 in} a positioned state by six mounting bolts 6 and one positioning pin 7. Here, on the mounting surface F of the load port apparatus A in each of the wafer process apparatuses B ₁ and B ₂ , female screws and pin holes (both not shown) corresponding to the bolt holes 4 and the pin holes 5 are provided. Yes. Therefore, the load port apparatus A can be mounted on any of the wafer process apparatuses B ₁ and B ₂ .

A table device T is disposed immediately below the wafer transfer window 3. As shown in FIG. 6, the central portion in the width direction of the table body 2 constituting the table device T has two stages for disposing the clamp device D, the base moving device E, and the carrier ID device (not shown). The notch 2 a on the near side (worker side) is closed by the lid 8. A carrier base 9 for installing one of the first and second wafer carriers C ₁ and C ₂ is attached to the upper surface of the table body 2. The carrier base 9 can be moved back and forth along the direction of the arrow (the loading / unloading direction Q of the wafers W ₁ and W ₂ ) with any of the wafer carriers C ₁ and C ₂ installed. That is, as shown in FIGS. 2 and 6, two guide bases 11 are carried on the upper surface of the table body 2 at a predetermined interval in the width direction (horizontal direction perpendicular to the carry-in / out direction Q). It is fixed along the outgoing direction Q. Two slide bodies 12 are fixed to the bottom surface of the carrier base 9 so as to correspond to the respective guide bases 11. Each slide body 12 is fitted in a concave groove portion 11 a formed on the upper surface portion of the corresponding guide base 11. Therefore, the carrier base 9 is slidable along the loading / unloading direction Q by sliding the slide bodies 12 while being guided by the guide bases 11.

_One of the wafer carriers C ₁ and C ₂ is installed on the carrier base 9. First, the first wafer carrier C ₁ will be described. As shown in FIG. 3, the first wafer carrier C ₁ is for storing wafers W ₁ having an outer diameter of 300 mm in multiple stages, and the main body 13 has a front surface that has a square shape when viewed from the front. And a back surface portion having an arc shape corresponding to the curvature of the wafer W ₁ . Here, the “front surface” refers to the side opposite to the wafer processing apparatuses B ₁ and B ₂ . The front surface portion is opened and is closed by a detachable lid (not shown). A flange portion 14 disposed near the wafer processing apparatuses B ₁ and B ₂ is attached to the peripheral portion. In addition, three pedestal portions 16 corresponding to first positioning members P ₁ (in the case of the present embodiment, three positioning pins 15 described later) protruding from the carrier base 9 are fixed to the bottom surface portion. ing. When the first wafer carrier C ₁ is installed on the carrier base 9 of the 300 mm load port apparatus A, the positioning pins 15 of the carrier base 9 are positioned on the positioning pin grooves provided on the pedestals 16. Enter 16a. Accordingly, the first wafer carrier C ₁ is positioned and installed on the carrier base 9.

The carrier base 9 is positioned at the front side (operator side) of the carrier base 9 at the substantially central portion in the width direction and at the back side (wafer processing apparatus B ₁ , B ₂ side) in the width direction at both ends. The pin 15 is protruded. Each positioning pin 15 enters the corresponding first wafer positioning pin groove 16a provided on the pedestal 16 of the carrier C _1. The upper end portion of each positioning pin 15 has a sharp end shape so as to facilitate entry into the corresponding positioning pin groove portion 16a. Further, in a substantially central portion of the bottom surface of the first wafer carrier C ₁ of the main body portion 13, after being installed in the carrier base 9, the clamp to be clamped by the clamping member 17 protrudes from below (see below) The part 18 is fixed.

The following describes the second wafer carrier C _2. As shown in FIG. 4, the second wafer carrier C ₂ is for storing wafers W ₂ having an outer diameter of 200 mm in multiple stages. And the main-body part 19 is substantially trapezoid shape in planar view, and the front part and the back part are opened. Therefore, unlike the first wafer carrier C _1, the lid is not resides. A pair of bottom ribs 20 project from the bottom surface portion at a predetermined interval in the width direction. Further, a pair of back ribs 21 connected to the pair of bottom ribs 20 project from the back surface portion. A right-angled corner portion 21a is formed at a connection portion between the pair of bottom ribs 20 and the pair of back ribs. Further, a positioning bar 22 is projected between the pair of bottom ribs 20 along the width direction (left-right direction). The positioning bar 22 has a substantially semicircular cross-sectional shape.

Similarly to the first wafer carrier C ₁ , the second wafer carrier C ₂ is positioned and installed on the carrier base 9 by the second positioning member P ₂ . The second positioning member P ₂ will be described. On the near side of the carrier base 9, a pair of corner portion positioning plates 23 are arranged at a predetermined interval in the width direction at a position slightly closer to the wafer processing apparatus B ₁ , B ₂ side than the positioning pins 15 on the near side. It is fixed with an interval (interval corresponding to the pair of bottom ribs 20). Each corner portion positioning plate 23 is substantially L-shaped in plan view, and is fixed with the inner portions 23a facing each other. Further, between the pair of positioning pins 15 on the back side, a substantially square groove forming plate 24 is fixed to face each other in plan view. Between and if the groove forming plate 24, the groove 25 for entering the second positioning bars 22 of the wafer carrier C ₂ is formed. Thus, the positioning base 15 for positioning and installing the first wafer carrier C ₁ and the second wafer carrier C ₂ are positioned on the carrier base 9 of the load port apparatus A of the present embodiment. Each corner positioning plate 23 and each groove forming plate 24 are installed without interfering with each other.

When the second wafer carrier C ₂ is installed on the carrier base 9, the pair of corner portions 21 a provided on the second wafer carrier C ₂ substantially contacts the inner portions 23 a of the corresponding corner portion positioning plates 23. Touch. At the same time, the positioning bar 22 of the second wafer carrier C ₂ enters the groove portion 25 formed between the groove forming plates 24. Thus, the second wafer carrier C ₂ is placed on the carrier base 9 in a state of being positioned in the front-rear direction and the left-right direction.

As shown in FIG. 5, when the first wafer carrier C ₁ is installed in the carrier base 9, the bottom surface portion of the pedestal 16, the second positioning member P ₂ for positioning the second wafer carrier C ₂ (Each corner portion positioning plate 23, each groove forming plate 24) is disposed slightly above the upper surface. Further, the second positioning member P ₂ for positioning the second wafer carrier C ₂ is located inside the mounting position of the first positioning member P ₁ (positioning pins 15) for positioning the first wafer carrier C ₁ . It is fixed to the direction. For this reason, the installation area of the second wafer carrier C ₂ in the carrier base 9 exists inside the first positioning member P ₁ (that is, a position not interfering with the first positioning member P ₁ ). Thus, when installed one of the wafer carrier C _1, C ₂ on the carrier base 9, does not interfere with other positioning members P _1, P _2. As a result of the above, even if each of the first and second wafer carrier C _1, C ₂ of the installation area of the carrier base 9 are duplicated, in the carrier base 9, the wafer carrier C ₁ of the first and second, Either C ₂ can be installed.

Next, the clamp device D will be described. As shown in FIG. 5, a clamping device D is disposed below the carrier base 9. And between each groove | channel formation board 24 in the carrier base 9, the clamp body through-hole 9a for letting the clamp body 17 pass is opened (refer FIG. 3). The clamping device D is for clamping the clamped portion 18 of the first wafer carrier C ₁ installed on the carrier base 9 with the clamp body 17 constituting the clamping device D. Thus, during operation of the load port device A, it is prevented to be removed the first wafer carrier C ₁ erroneously operator. In the case of the second wafer carrier C _2, since the second wafer carrier C ₂ is prevented from being removed by being covered with a carrier cover 26 which will be described later, the clamping device D does not operate.

As shown in FIGS. 5 and 6, the clamp body 17 constituting the clamp device D is substantially F-shaped in a side view, and a rotation support portion 17 a provided at a substantially middle portion in the height direction includes: A bracket 27 attached to the bottom surface of the carrier base 9 is rotatably supported. The lower end of the clamp body 17 is connected to a cylinder rod 29 a of the clamp cylinder 29 via a link plate 28. The clamp cylinder 29 is horizontally supported by a cylinder bracket 31 attached to the bottom surface of the carrier base 9. With the cylinder rod 29a of the clamp cylinder 29 moving forward (protruding), the clamp body 17 is rotated in the clockwise direction around the rotation fulcrum 17b, and the upper end of the clamp body 17 is from the upper surface of the carrier base 9. protrudes to lock the projections 18a of the clamp portion 18 attached to the first bottom surface portion of the wafer carrier C _1. As a result, the first wafer carrier C ₁ cannot be removed from the carrier base 9. Further, in a state in which the cylinder rod 29a of the clamp cylinder 29 is retracted (retracted), the clamp body 17 is rotated counterclockwise around the rotation fulcrum 17b, and the upper end portion thereof is the carrier base. 9 is retracted to the clamp body through hole 9a. Then, the engagement between the clamp body 17 and the protrusion 18a of the clamped portion 18 is released. At this time, the link plate 28 is disposed obliquely in a side view. As a result, the first wafer carrier C ₁ can be detached from the carrier base 9.

The first wafer carrier C ₁ installed on the carrier base 9 and fixed by the clamping device D is advanced and retracted along the loading / unloading direction Q of the wafer W ₁ by the action of the base moving device E. The base moving device E will be described. As shown in FIGS. 6 and 7, a cylinder bracket 32 is attached to the bottom surface portion of the table body 2, and an air cylinder (base moving cylinder 33) is horizontally attached to the cylinder bracket 32. . A hand clamp detection dog 35 is attached to the cylinder rod 33a of the base moving cylinder 33 via an adapter 34, and the same axis as the cylinder rod 33a is formed from the dog 35 so as to be thinned in two stages. The stepped rod 36 is extended. The first stepped portion 36 a of the stepped rod 36 is inserted through the insertion hole 37 a of the connecting block 37 attached to the bottom surface portion of the carrier base 9. Similarly, the top body 38 is inserted into the second stepped portion 36b, and a washer 39 is attached to the tip thereof. Two compression springs 41 are elastically mounted in series on the first and second stepped portions 36 a and 36 b of the stepped rod 36 via a piece body 38. Due to the elastic restoring force of each compression spring 41, the connecting block 37 is always pressed against the proximal end portion 36 c of the stepped rod 36. A sensor bracket 42 is attached to the side surface of the connection block 37, and a limit switch 43 is attached to the sensor bracket 42. The detection roller 43a of the limit switch 43 is in contact with the dog 35 and always exhibits a detection state.

When the cylinder rod 33a of the base moving cylinder 33 is retracted, the stepped rod 36 is also retracted. Then, each compression spring 41 is compressed, the connecting block 37 is pushed by the elastic restoring force at that time, and moves in the same direction as the cylinder rod 33a. As a result, the first wafer carrier C ₁ installed on the carrier base 9 moves along the loading / unloading direction Q, and the first wafer carrier C ₁ is at the wafer loading / unloading position (position where the wafer W ₁ is loaded / unloaded). Placed in. At this time, the detection roller 43a of the limit switch 43 remains in contact with the dog 35 and is moved while maintaining its detection state. This state is indicated by a one-dot chain line in FIGS.

In a state where the first wafer carrier C ₁ is disposed on the wafer loading and unloading position and to advance the cylinder rod 33a of the base moving cylinder 33, also moves forward stepped rod 36. Then, the connecting block 37 is pushed forward by the proximal end portion 36 c of the stepped rod 36. As a result, the first wafer carrier C ₁ installed on the carrier base 9 is moved along the loading and unloading direction Q, the first wafer carrier C ₁ Carrier installation position (the first wafer carrier C ₁ detachably is performed Position). Also at this time, the detection roller 43a of the limit switch 43 remains in contact with the dog 35 and is moved while maintaining its detection state.

As shown in FIG. 8, if the first wafer carrier C ₁ is used, an operator's hand is mistakenly placed between the apparatus main body 1 of the load port apparatus A and the flange portion 14 of the first wafer carrier C _1. If there is a foreign object between the two, even if the cylinder rod 33a is retracted, a gap of a predetermined length L is formed between the base end portion 36c of the stepped rod 36 and the connecting block 37. Arise. Thus, the first wafer carrier C ₁ is, may not be placed on the wafer loading and unloading position. However, the base moving device E according to the present embodiment is configured such that the detection roller 43a of the limit switch 43 is separated from the dog 35 when a gap is generated between the base end portion 36c of the stepped rod 36 and the connecting block 37. ing. When this signal is sent to the control device, the operation of the base moving cylinder 33 is stopped. As a result, it is possible to prevent the problem that the wafer W ₁ is loaded / unloaded without the first wafer carrier C ₁ being disposed at the wafer loading / unloading position. Effect described above is also performed in the case of the second wafer carrier C _2.

Next, the carrier cover 26 will be described. As shown in FIGS. 1 and 2, the load port apparatus A of this embodiment, a carrier cover 26 for the second covering the wafer carrier C ₂ is mounted. Inner width of the carrier cover 26 is slightly wider than the outer width of the table body 2, its height is slightly higher than the second height of the wafer carrier C _2. And it bends gently toward the back side from the opening side. One end of a substantially triangular connecting plate 44 is pivotally attached to both side walls 26a of the carrier cover 26. The other end of the connecting plate 44 is attached to the carrier cover 26. Thereby, the carrier cover 26 can be rotated around the rotation fulcrum 44 a of each connecting plate 44. A substantially L-shaped bracket 45 is fixed to the front end portion of the carrier cover 26 in use, and a magnet 46 is attached to the upper end portion thereof. The magnet 46 is attracted to a magnet attracting plate 47 attached to the apparatus main body 1 of the load port apparatus A when the carrier cover 26 is rotated. This prevents the carrier cover 26 from being detached due to vibration or the like. In FIG. 1, reference numeral 48 denotes a handle for rotating the carrier cover 26.

As described above, the carrier cover 26 is for covering the second whole wafer carrier C _2. As a result, it is possible to prevent the operator from accidentally removing the second wafer carrier C ₂ while the load port apparatus A is in operation. When the load port device A is not operating and when the first wafer carrier C ₁ is installed on the carrier base 9, the carrier cover 26 is not used and is disposed below the table device T. The installation work of the wafer carriers C ₁ and C ₂ is not hindered.

The operation of the load port apparatus A of the present embodiment will be described in the case where the first wafer carrier C ₁ is used. When the first wafer carrier C ₁ is installed on the carrier base 9, the cylinder rod 33 a of the base moving cylinder 33 is advanced, and the carrier base 9 is disposed at a carrier installation position away from the apparatus main body 1. For this reason, the first wafer carrier C ₁ and the apparatus main body 1 do not interfere with each other. Each positioning pin 15 of the carrier base 9, enters the first wafer carrier C ₁ of the positioning pin groove 16a of the pedestal 16 attached to the bottom portion of the main body portion 13. At this time, the second positioning member P ₂ for positioning the second wafer carrier C ₂ (each corner portion positioning plate 23 and each groove forming plate 24) is the first wafer carrier in which each positioning pin 15 is inserted. because it is located below the bottom surface portion of the C _1, never both interfere. Thereby, the first wafer carrier C ₁ is positioned and installed with respect to the carrier base 9. Then, the clamp cylinder 29 is operated, and the clamp body 17 is locked to the protruding portion 18a of the clamped portion 18. As a result, the first wafer carrier C ₁ cannot be removed from the carrier base 9, and the operator is prevented from removing it accidentally while the load port apparatus A is in operation.

Then, the cylinder rod 33a of the base moving cylinder 33 is retracted. The first wafer carrier C ₁ is disposed at the wafer loading / unloading position, and the flange portion 14 is disposed close to the periphery of the wafer transfer window 3 of the apparatus main body 1. In this state, the lid (not shown) of the first wafer carrier C ₁ is removed and stored in the first wafer carrier C ₁ by a robot (not shown) built in the wafer processing apparatus B _1. Wafer W ₁ is taken out. The wafer W _{1 that} has been subjected to the predetermined processing by the wafer processing apparatus B ₁ is again stored in the first wafer carrier C ₁ by the robot. When the same action as described above is performed on each wafer W ₁ , the lid is attached and the cylinder rod 33 a of the base moving cylinder 33 is advanced. Thus, the first wafer carrier C ₁ is arranged in a carrier installation position. The first wafer carrier C ₁ is replaced, and the same operation as described above is performed on each new wafer W ₁ .

Next, an operation when the second wafer carrier C ₂ is used will be described. In this case, the clamp body 17 of the clamp device D is retracted to the clamp body through hole 9 a in the carrier base 9. As in the case of the first wafer carrier C ₁ , the second wafer carrier C ₂ is installed on the carrier base 9 arranged at the wafer installation position. At this time, the second respective corner portions 21a of the wafer carrier C ₂ is, while being abutted to the inner portion 23a of the corresponding corner positioning plate 23, the positioning bar 22 which projects from the bottom portion of the main body portion 19, a groove It enters into the groove 25 of the forming plate 24. At this time, the second positioning members for positioning the second wafer carrier C ₂ (each corner portion positioning plate 23 and each groove forming plate 24) serve as the first positioning member for positioning the first wafer carrier C _1. Since it is fixed inside P ₁ (each positioning pin 15), the second wafer carrier C ₂ and the first positioning member P ₁ do not interfere with each other. Thus, the second wafer carrier C ₂ is positioned and installed with respect to the carrier base 9. The carrier cover 26 is rotated upward, the whole of the second wafer carrier C ₂ is covered. As a result, it is possible to prevent the operator from accidentally removing the load port device A during operation.

Then, the cylinder rod 33a of the base moving cylinder 33 is retracted, the second wafer carrier C ₂ is arranged in the wafer loading and unloading position. The subsequent operation is the same as that of the first wafer carrier C ₁ .

As described above, in the load port apparatus A of this embodiment, any of the wafer carriers C ₁ and C ₂ can be installed on the carrier base 9. For this reason, only one type of load port apparatus A is required for two types of wafer process apparatuses B ₁ and B ₂ having the same mounting surface F, and when the load port apparatus A breaks down, other wafer process apparatuses B _The load port device A attached to ₁ and B ₂ can also be removed and used. As a result, the processing of the wafers W ₁ and W ₂ can be made efficient.

The carrier cover 26 attached to the load port device A of the present embodiment is attached to the table body 2 via each connection plate 44 and is rotated around the rotation fulcrum 44 a of the connection plate 44. Thus, the second wafer carrier C ₂ is covered. For this reason, the operation of covering the second wafer carrier C ₂ is easy, and when the first wafer carrier C ₁ is used, it is not necessary to attach or remove it. However, the carrier cover 26 may be a separate body and detachably attached to the load port device A.

In the present specification, the load port apparatus A has been described in which both the 300 mm first wafer carrier C ₁ and the 200 mm second wafer carrier C ₂ can be installed. However, a configuration in which a wafer carrier in which a wafer having a size other than this (for example, an outer diameter of 150 mm) is stored may be installed.

It is a perspective view of load port device A concerning the present invention. It is a side view similarly. FIG. 5 is a perspective view of a state in which a first wafer carrier C ₁ is installed on a carrier base 9. Similarly, a perspective view of a state of installing the second wafer carrier C _2. It is a side view of the clamp apparatus D. It is a top view of clamp device D and base movement device E. 4 is a side view of a base moving device E. FIG. It is an operation explanatory view similarly.

Explanation of symbols

A: Load port equipment B ₁ , B ₂ : Wafer process equipment (semiconductor manufacturing equipment)
C ₁ and C ₂ : Wafer carrier
D: Clamp device
F: Mounting surface P ₁ , P ₂ : Positioning member
Q: Loading / unloading direction W ₁ , W ₂ : Wafer
1: Device body
9: Career base (carrier table)
15: Positioning pin (first positioning member)
23: Corner portion positioning plate (second positioning member)
24: Groove forming plate (second positioning member)
26: Carrier cover (cover member)

Claims (4)

An apparatus main body detachably mounted on a semiconductor manufacturing apparatus;
A carrier table for installing a wafer carrier for storing a wafer to be processed by the semiconductor manufacturing apparatus;
A load port device to be mounted on a semiconductor manufacturing apparatus having the same mounting surface configuration on which the device body is mounted,
The carrier table includes first and second positioning members for positioning the first and second wafer carriers having different sizes and installing them at overlapping positions,
Each of the first and second positioning members has an arrangement structure in which one wafer carrier is positioned and installed so that the positioning member of the other wafer carrier does not interfere with each other. apparatus. The first positioning member for positioning the larger first wafer carrier is composed of a plurality of positioning pins provided outside the installation area of the second wafer carrier, and the second positioning member is the first wafer. The load port device according to claim 1, comprising a plurality of positioning plates having a height that does not interfere with a bottom surface portion of the carrier in a state where the carrier is installed. The carrier table is provided with a clamping device for clamping the first wafer carrier in order to prevent the first wafer carrier from being removed during operation of the load port device.
The load port device according to claim 2, wherein the clamp body constituting the clamp device is disposed so as to be retractable from the second wafer carrier in the installed state. In order to prevent the second wafer carrier from being removed during the operation of the load port device, the cover member for covering the second wafer carrier avoids interference with the first wafer carrier in the installed state. The load port device according to claim 2 or 3, wherein the load port device is attached.

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