TRANSPORT MODULE
A front-opening wafer transport module has a container portion with transparent shell and a central support structure which includes a machine interface exposed at the bottom of the module and integral wafer support columns extending upwardly in the container portion for supporting wafers. Additionally, the side walls of the shell have recessed portions with engagement members that cooperate with engagement members on removable handles. The handles utilize detents to lock into place in the recesses on the side walls of the carrier. Attachment of the handles to the side walls is accomplished without breaks between the interior and exterior of the module and without separate fastners.
This application is a Continuation of application Ser. No. 10/848,096, filed May 18, 2004, which will issue May 13, 2008, as U.S. Pat. No. 7,370,764, which is a Continuation-in-Part of application Ser. No. 09/476,546, filed Jan. 3, 2000, which is a Continuation of application Ser. No. 08/891,644, filed Jul. 11, 1997 issued as U.S. Pat. No. 6,010,008 which are hereby incorporated herein by reference in their entirety.
BACKGROUND OF THE INVENTIONThis invention relates to carriers for semiconductor wafers and more particularly it relates to a closeable container for storing and transporting wafers.
Sealable enclosures, generally termed transport modules, have been utilized in the semiconductor processing industry for a number of years for storing and transporting wafers between processing steps and/or between facilities. Semiconductor wafers are notoriously vulnerable to damage from contaminants such as particles. Extraordinary measures are taken to eliminate contaminants in cleanrooms and other environments where semiconductor wafers are stored or processed into circuits.
For wafers in the range of 200 mm and smaller, containers known as SMIF pods (standardized mechanism interface) have been utilized to provide a clean sealed mini-environment. Examples of these pods are shown in U.S. Pat. Nos. 4,532,970 and 4,534,389. Such SMIF pods typically utilize a transparent box-shaped shell with a lower door frame or flange defining an open bottom and a latchable door. The door frame clamps onto processing equipment and a door on the processing equipment and the lower SMIF pod door closing the open bottom are simultaneously lowered downwardly from the shell into a sealed processing environment in said processing equipment. A separate H-bar carrier positioned on the top surface inside of the SMIF pod door and loaded with wafers is lowered with the pod door for accessing and processing said wafers. In such pods the weight of the wafers would be directly on the door during storage and transport.
The semiconductor processing industry is moving toward utilization of larger and heavier wafers, specifically 300 mm wafers. Transport modules for such modules, by way of developing industry standards, will utilize a front opening door for insertion and removal of the wafers as opposed to a bottom door that drops downwardly from the module. The door would not support the load of the wafers, rather a container portion which would include a clear plastic (such as polycarbonate) shell and other members or supporting the wafers molded from a low particle generating plastic (such as polyetheretherketone) would carry the load of the wafers. Such container portions necessarily are made from multiple components assembled together.
In handling and processing semiconductor wafers, static electricity is a continuing concern. Electrostatic discharges can damage or ruin semiconductor wafers. Therefore, means must be taken to minimize any such generation of potentials which may cause static electric discharges. H-bar carriers have been manufactured with convention static dissipative materials such as carbon filled polyetheretherketone (PEEK) and polycarbonate (PC).
The developing industry standards for such 300 mm modules require a machine interface, such as a kinematic coupling, on the bottom of the module to repeatedly and with precision align the module with respect to the processing equipment. This allows robotic handling means to engage the door on the front side of the module, open the door, and with the necessary amount of precision grasp and remove specific horizontally arranged wafers. It is highly critical to have the wafers positioned at a particular height and orientation with reference to the equipment machine interface such that the wafers will not be located and damaged during the robotic withdrawal and insertion of said wafers.
Due to inconsistencies in molding plastic parts assembly of such plastic parts lead to inconsistencies, such as open cracks between parts and the stacking of the tolerances of each individual part leading to undesirable variations in critical dimensions.
Known front opening 300 mm transport modules utilize multiple component parts including multiple components between the equipment interface and the wafer supports. This can lead to difficulty in producing modules with acceptable tolerances between the wafer planes and the equipment interface. Additionally, such modules have a path to ground from the wafer shelves to the equipment interface through several different components including metallic screws.
The 300 mm wafers are substantially greater in size and weight than the 200 mm modules; therefore, a structurally stronger module for transporting batches of wafers is required. Typically with the 200 mm SMIF pods the module was simply carried manually by grasping the lower edges at the juncture of the shell door flange and the door. Handles have been provided on the top of the shell portion for bottom opening pods. For carrying the larger, heavier, and bulkier modules for 300 mm wafers side handles are appropriate. For certain applications, the movement of the 300 mm module may be exclusively by way of robotic means thus not requiring handles or other means for manually transporting the container. Thus, a robotic lifting handle should be provided and any manual lifting handles should be easily removable.
Additionally, due to the high susceptibility of wafers to contamination by particles, moisture or other contaminants it is ideal to have a minimal number of potential entry paths to the interior of the module. Paths or breaks in the plastic between the interior and exterior of the pod such as for fasteners or at the junction of separate component parts of the module are to be avoided. Any such path required should be adequately sealed.
Additionally, the use at any location in the pod of metallic fasteners or other metal parts are highly undesirable in semiconductor wafer carriers or containers. Metallic parts generate highly damaging particulates when rubbed or scrapped.
SUMMARY OF THE INVENTIONA front-opening wafer transport module has a container portion with transparent shell and a central support structure which includes a machine interface exposed at the bottom of the module and integral wafer support columns extending upwardly in the container portion for supporting wafers. Additionally, the side walls of the shell have recessed portions with engagement members that cooperate with engagement members on removable handles. The handles utilize detents to lock into place in the recesses on the side walls of the carrier. Attachment of the handles to the side walls is accomplished without breaks between the interior and exterior of the module and without separate fastners.
A feature and advantage of the invention is that there are no stacking of tolerances among parts relative to the machine interface level and the levels of the wafers on the wafer shelves. Where multiple components define the machine interface level and the wafer levels, each part has a separate manufacturing tolerance and when such components are assembled into the module the tolerances are cumulative. This translates into a higher rejection of individual parts and/or a higher rejection level of assembled modules. The instant invention utilizes a single integral component for the machine interface and the wafer support members.
Another advantage and feature of the invention is that a non-interrupted path-to-ground extends from each wafer support shelf to the machine interface.
Another object and advantage of the invention is that the central support structure which holds the wafers is assembled into the shell through a lower opening and is secured in place by a rotation of the central support structure with respect to the shell. No metallic fasteners are used.
Additionally, the central support structure engages and locks at the top of the shell by way of a top portion with a collar that extends into an aperture in the top of the shell and robotic lifting flange that slidably engages the top portion of the central support structure and also thereby non-rotatably locks the support structure to the shell. Again, no metallic fasteners or components are used.
Another object and advantage of the invention is that the breaks or openings in the module between the interior and exterior are sealed such as by elastomeric seals. The breaks or openings other than at the front door are circular in shape and are sealed such as by O-rings.
Anther object and advantage of the invention is that handles may be easily added and removed to the module without utilizing metallic fasteners or other separate fasteners and without breaks or openings in the solid side walls.
Another object and advantage of the invention is that the component parts may be easily disassembled for cleaning and/or replacement for maintenance.
Referring to
Referring to
The shell 58 has a top 64 with an aperture 66, a bottom 68 with a lower opening 70, an open front side 72, a left side wall 74, and a right side wall 76 both with handle receiving portions configured as recesses 78 extending inwardly. Notably, the recesses project into the interior but have no cracks, breaks, openings or apertures between the interior 74 and the exterior of the container. The side walls may be continuous and solid. The handle receiving portions include a recessed planar portion 80 which is part of the side walls. Shelves may be as shown in U.S. patent application Ser. No. 09/523,745 to David Nyseth filed Mar. 13, 2000. Said application is hereby incorporated by reference.
The central support structure 60 is comprised of a bottom portion with an equipment interface 86 configured as a plate with three interface structures 88 which comprise a kinematic coupling. Integral with the machine interface portion 86 are a pair of wafer support columns 92 each of which comprise a plurality of shelves 94 and defining a wafer receiving region 95. Each shelf having wafer engagement portions 96. The wafer support columns 92 are integral with a top portion 100 which includes a spanning member 101 which extends between the tops 98 of the support columns 92 and also includes a first connecting member 104.
The central support structure 60 assembles upwardly into the lower opening 70 of the shell 58 with the first connecting member extending upwardly through the aperture 66 on the top 64 of the shell 58. The second connecting member 106 slidably engages on the first connecting member 104 for retention of the central support structure in the shell. A second connecting member 106 which is integral with a robotic lifting handle 108 configured as a flange. The shell also includes first engagement members 112 as part of a support structure engagement portion 113 which engage with second engagement members 114 as part of a shell engagement portion 115 on the central support structure. These cooperating engagement members also secure the central support structure to and within the shell. A first O-ring 118 engages between the top portion 100 of the central support structure and the top 64 of the shell to create a seal thereabout. Similarly, a second O-ring 120 seals between the machine interface portion 86 and the bottom 68 of the shell. Referring to
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The equipment interface 86 as best shown in
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Significantly, this particular configuration allows easy installation and removal of the handle such as for cleaning or storage or when a robotic application does not require use of the handle. Additionally, the integrity of the separation between the interior of the transport module and the exterior is not affected. In other words, there are no breaks, openings or fasteners through the side walls to accomplish the connection of the handle to said shell.
Referring to
The shell portion of the material is preferably injection molded form polycarbonate or polyetherimide or the like. The central support structure is also ideally integrally injection molded and may be formed from carbon fiber filled PEEK or similar materials, ideally which provide a static dissipative feature. The handles may be injection molded from polycarbonate or polyetherimide. The top second connecting member including the robotic lifting handle may be also formed from carbon fiber filled PEEK or other static dissipative injection molded material.
The mechanisms utilized for latching the doors can be varied and may be such as shown in U.S. Pat. No. 4,995,430 to Anthony C. Bonora et al., U.S. Pat. No. 5,915,562 to Nyseth, or similar mechanisms.
Referring to
The present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof; and it is, therefore, desired that the present embodiment be considered in all respects as illustrative and not restrictive, reference being made to the appended claims rather than to the foregoing description to indicate the scope of the invention.
Claims
1-21. (canceled)
22. A sealable enclosure for receiving and holding a plurality of wafers horizontally, the enclosure comprising:
- a container portion with a top, a bottom, a back, an open front, an open interior and comprising a forwardly projecting door flange with a plurality of recesses therein, a pair of sides, a plurality of shelves positioned in the open interior at each side of the container portion for holding the wafers axially aligned in said interior; and
- a door for fitting within the door flange and sealingly closing the open front, the door comprising a plurality of latch mechanisms that extend and retract latches to engage the recesses in the door flange, each latch mechanism including a manual opening handle for operating the latch mechanism manually and each latch mechanism also including structure defining a key slot for operating the latch mechanism robotically.
23. The enclosure of claim 22, further comprising a kinematic coupling on the bottom of the enclosure.
24. The enclosure of claim 22, wherein the plurality of shelves and the kinematic coupling are integrally formed of static dissipative material, thereby forming an uninterrupted electrical path to ground.
25. The enclosure of claim 22, the container portion defining a handle receiving structure on an outside surface of each of the pair of sides, each handle receiving structure adapted to receive a removable handle and comprising a pair of spaced apart linear guide strips, whereby the removable handle is linearly slidable between the guide strips to couple the removable handle with the container portion.
26. The enclosure of claim 25, wherein each linear guide strip comprises a planar portion oriented generally parallel with the side and spaced apart from the side, the planar portions of the each of the spaced apart guide strips being vertically registered and extending toward each other such that the guide strips together define a handle receiving slot for linearly slidingly receiving the handle therein.
27. The enclosure of claim 25, in combination with a pair of handles, wherein each of the handles is linearly slidably engageable with a separate one of the handle receiving structures, and wherein each handle comprises a detent for securing the handle in a favored position.
28. The enclosure of claim 22, wherein an inside facing surface of the door has a central recess extending from the top of the door to the bottom of the door and wherein a wafer restraint is positioned in the central recess.
29. A sealable transport module for receiving and holding a plurality of wafers horizontally, the module comprising:
- a container portion with a top, a bottom, a back, a pair of opposing sides, an open front, and an open interior, the open front being defined by a door frame with a plurality of recesses therein, the container portion further including a plurality of shelves positioned in the open interior proximate each side of the container portion for holding the wafers axially aligned in said interior; and
- a door selectively engageable in the door frame to sealingly close the open front, the door comprising at least one latch mechanism that extends and retract latches to engage the recesses in the door flange, the at least one latch mechanism including means for operating the latch mechanism manually and the at least one latch mechanism also including means for operating the latch mechanism robotically.
30. The module of claim 29, wherein the means for operating the at least one latch mechanism manually comprises a manual opening handle operably coupled with the at least one latch mechanism.
31. The module of claim 29, wherein the means for operating the at least one latch mechanism robotically comprises structure defining a key slot operably coupled with the at least one latch mechanism.
32. The module of claim 29, further comprising a kinematic coupling on the bottom of the enclosure.
33. The module of claim 32, wherein the plurality of shelves and the kinematic coupling are integrally formed of static dissipative material, thereby forming an uninterrupted electrical path to ground.
34. The module of claim 29, the container portion defining a handle receiving structure on an outside surface of each of the pair of opposing sides, each handle receiving structure adapted to receive a removable handle and comprising a pair of spaced apart linear guide strips, whereby the removable handle is linearly slidable between the guide strips to couple the removable handle with the container portion.
35. The module of claim 34, wherein each linear guide strip comprises a planar portion oriented generally parallel with the side and spaced apart from the side, the planar portions of the each of the spaced apart guide strips being vertically registered and extending toward each other such that the guide strips together define a handle receiving slot for linearly slidingly receiving the handle therein.
36. The module of claim 34, in combination with a pair of handles, wherein each of the handles is linearly slidably engageable with a separate one of the handle receiving structures, and wherein each handle comprises a detent for securing the handle in a favored position.
37. The module of claim 29, wherein an inside facing surface of the door has a central recess extending from the top of the door to the bottom of the door and wherein a wafer restraint is positioned in the central recess.
38. A sealable enclosure for transporting a plurality of semiconductor wafers, the enclosure comprising:
- a container portion with a top, a bottom, a back, a pair of opposing sides, an open front, and an open interior, the open front being defined by a door frame with a plurality of recesses therein, the container portion further including a plurality of shelves positioned in the open interior proximate each side of the container portion for holding the wafers axially aligned in said interior; and
- a door selectively engageable in the door frame to sealingly close the open front, the door comprising at least one latch mechanism that extends and retract latches to engage the recesses in the door flange, the at least one latch mechanism including a handle and separate structure defining a key slot, each operably coupled with the latch mechanism to enable the latches to be selectively extended and retracted.
39. The enclosure of claim 38, the container portion defining a handle receiving structure on an outside surface of each of the pair of sides, each handle receiving structure adapted to receive a removable handle and comprising a pair of spaced apart linear guide strips, whereby the removable handle is linearly slidable between the guide strips to couple the removable handle with the container portion.
40. The enclosure of claim 39, wherein each linear guide strip comprises a planar portion oriented generally parallel with the side and spaced apart from the side, the planar portions of the each of the spaced apart guide strips being vertically registered and extending toward each other such that the guide strips together define a handle receiving slot for linearly slidingly receiving the handle therein.
41. The enclosure of claim 39, in combination with a pair of handles, wherein each of the handles is linearly slidably engageable with a separate one of the handle receiving structures, and wherein each handle comprises a detent for securing the handle in a favored position.
Type: Application
Filed: May 12, 2008
Publication Date: Dec 11, 2008
Inventors: David L. Nyseth (Plymouth, MN), Dennis J. Krampotich (Shakopee, MN), Todd M. Ulschmid (New Prague, MN), Gregory W. Bores (Prior Lake, MN)
Application Number: 12/119,240
International Classification: B65D 85/86 (20060101); H01L 21/67 (20060101);