KR200429043Y1 - Electronic device manufacturing chamber - Google Patents

Abstract

In a first aspect, a first multi-piece chamber is provided. The first multi piece chamber comprises: (1) a central piece having a first side and a second side; (2) a first side piece coupled to the first side of the center piece; And (3) a second side piece coupled to the second side of the center piece. The central piece, the first side piece and the second side piece, when joined together, form a substantially cylindrical inner chamber region. Many other aspects are provided.

Transfer module, transfer chamber, support

Description

Electronic device manufacturing chamber {ELECTRONIC DEVICE MANUFACTURING CHAMBER}

1 is a top view of a first exemplary multi piece electronic device manufacturing chamber in accordance with some embodiments of the present invention.

2A is an exploded perspective view of an exemplary first exemplary multi-piece electronic device manufacturing chamber in accordance with some embodiments of the present invention.

2B is a perspective view of the first chamber of FIG. 2A when assembled;

FIG. 2C is a plan view of the first chamber of FIG. 2A.

FIG. 2D is a side view of the first chamber of FIG. 2A.

FIG. 2E is a perspective view of the first chamber of FIG. 2A using another lid design. FIG.

3 is a perspective view of a second exemplary multi-piece electronic device manufacturing chamber in accordance with some embodiments of the present invention.

4 is an exploded perspective view of an exemplary second exemplary multi-piece electronic device manufacturing chamber in accordance with some embodiments of the present invention.

5 is a side view of a first piece of an exemplary second exemplary multi piece electronic device manufacturing chamber, seen within a container, in accordance with some embodiments of the present invention.

6 is a side view of a second piece of an exemplary second exemplary multi piece electronic device manufacturing chamber, seen within a container, in accordance with some embodiments of the present invention.

7 is a perspective view of an electronic device manufacturing chamber support in accordance with some embodiments of the present invention.

8 is a perspective view of an exemplary electronic device manufacturing chamber support in accordance with some embodiments of the present invention.

9 is a perspective view of the exemplary electronic device manufacturing chamber support of FIG. 8 in accordance with some embodiments of the present invention.

10 is a perspective view of the exemplary electronic device manufacturing chamber support of FIG. 9 showing support of the electronic device manufacturing chamber.

11 is a perspective view of an exemplary base frame / center chamber piece assembly that may be transported to the unit.

12 is a perspective view of a side piece / base frame assembly that may be transported to the unit.

<Explanation of Signs of Major Parts of Drawings>

101: first chamber 109: first piece 111: second piece 113: third piece

201a, 201b, 201c, 201d, 201e, 201f: facets

203, 205: cylindrical walls 207, 209: side walls

211a, 211b, 211c: notch

213, 215, 217, 221, 223a, 223b, 223c: opening

225: pin structure 227: bottom 229: flat portion 231: domed portion

This application claims the title "SEMICONDUCTOR DEVICE MANUFACTURING TOOL AND METHOD FOR USING THE SAME" (Docket No. 8840 / L) filed June 2, 2004 and US Provisional Application No. 8 / 576,902. The title "ELECTRONIC DEVICE MANUFACTURING TOOL AND METHOD FOR USING THE SAME" (Docket No. 8840 / L2) under the number 60 / 587,109 is given priority. Each provisional application is incorporated herein by reference.

 The present invention generally relates to the manufacture of flat panel displays and / or electronic devices, and more particularly, to an electronic device manufacturing chamber and a method of forming the same.

As the size of substrates used in flat panel displays increases, the size of electronic device manufacturing chambers (eg, process and / or transfer chambers) used in the manufacture of larger flat panel displays must also increase. However, due to the overall size and / or weight of the chamber, the difficulty of manufacturing and transporting such a chamber also increases. Thus, there is a need for improved electronic device manufacturing chambers used in the manufacture of large flat panel displays and improved methods of transporting such chambers.

In a particular embodiment of the present invention, (1) a central piece having a first side and a second side; (2) a first side piece coupled to the first side of the center piece; And (3) a second side piece coupled to the second side of the center piece. The center piece, the first side piece and the second side piece, when joined together, form a substantially cylindrical inner chamber region.

In certain embodiments of the present invention, (1) a first open side; (2) a second open side opposite the first open side; (3) a first facet between the first open side and the second open side, the first facet being coupled to the chamber and having an opening in which the substrate can pass through the opening; And (4) a central piece opposite the first facet and having a second facet between the first open side and the second open side. The second facet is coupled to the chamber and has at least two vertically stacked openings, each sized to allow the substrate to pass through the openings. The multi-piece chamber comprises (1) a first side piece coupled with a first open side of the center piece and having at least one first facet having an opening sized to allow the substrate to pass therethrough; And (2) a second side piece associated with the second open side of the central piece, the second side piece having at least one first facet having an opening sized for the substrate to pass therethrough. When the first side piece, the second side piece and the center piece are joined together, the opening of the first facet of the first side piece, the opening of the first facet of the second side piece, and the first of the second facet of the center piece The opening is substantially the same height.

 In a particular embodiment of the present invention, (1) a first piece; And (2) at least one second piece coupled to the first piece to form a multi piece chamber. Each piece size complies with at least one of the ground and air transport regulations, and the overall size of the multi-piece chamber does not follow at least one of the ground and air transport regulations.

In a particular embodiment of the present invention, (1) a central piece comprising a bottom having a first side, a second side and a domed portion; (2) a first side piece engaged with the first side of the center piece; And (3) a second side piece coupled with the second side of the center piece.

In a particular embodiment of the present invention, a multi piece chamber is provided that includes a center piece having a bottom having a first side, a second side and a domed portion, and a flat portion. The flat portion has a first thickness and the domed portion has a second thickness less than the first thickness. The multi piece chamber also includes: (1) a first side piece coupled with the first side of the central piece; And (3) a second side piece coupled with the second side of the center piece.

In a particular embodiment of the present invention, a sixth multi piece chamber is provided. (1) a first side; (2) a second side; (3) a first facet comprising at least one opening of a size through which the substrate can pass; And (4) a central piece having a second facet each comprising at least three openings that are sized to pass through the substrate. The multi piece chamber comprises (1) a first side piece coupled with a first side of a central piece; And (2) a second side piece coupled with the second side of the center piece.

In a particular embodiment of the present invention, (1) a central piece having a first side and a second side; (2) a first side piece coupled to the first side of the center piece; And (3) a second side piece coupled with the second side of the center piece. The first side of the central piece includes at least one first notch to allow the substrate to rotate within the multi piece chamber and to be transferred from the multi piece chamber to a chamber coupled to the first side piece of the multi piece chamber. do.

In a particular embodiment of the present invention, (1) a central piece having a first side and a second side; (2) a first side piece coupled with the first side of the center piece and having at least one fin structure to reduce movement of the side walls of the first side piece; And (3) a second side piece coupled with the second side of the center piece.

In a particular embodiment of the present invention, (1) a central piece comprising a first side and a second side; And (2) a first side piece engaged with the first side of the center piece. The first side piece includes at least one support to reduce movement of the sidewall of the first side piece. The multi piece chamber also includes a second side piece coupled with the second side of the center piece. The second side piece includes at least one support to reduce movement of the sidewalls of the second side piece. Furthermore, the central piece, the first side piece and the second side piece, when joined together, constitute a substantially cylindrical inner chamber region.

In a particular embodiment of the present invention, (1) a central piece having a first side and a second side; (2) a first side piece engaged with the first side of the center piece; (3) a second side piece coupled with the second side of the center piece; And (4) a cover covering at least the center piece. The cover includes a flat portion and a plurality of support members that reduce movement of the flat portion in the vertical direction.

In a particular embodiment of the present invention, (1) a central piece having a first side and a second side; (2) a first side piece engaged with the first side of the center piece; (3) a second side piece coupled with the second side of the center piece; And (4) a cover covering at least the center piece. The cover includes at least one hatch that allows access to the interior area of the multi piece chamber without having to remove the cover.

In certain embodiments of the present invention, (1) determining the overall size of at least one of the electronic device manufacturing chambers; (2) disassembling the multi-piece electronics manufacturing chamber into a plurality of pieces to determine how to disassemble the size of each of the plurality of pieces so as to conform to either ground or air transport regulations; And (3) manufacturing a plurality of pieces. A multi piece electronic device manufacturing chamber is provided. The overall size of the multi-piece chamber does not follow at least one of the ground or air transport regulations.

In a particular embodiment of the present invention, (1) transporting a first piece of the plurality of chamber pieces via either ground or air transport; (2) transporting a second of the plurality of chamber pieces via either ground or air transport; And (3) during transportation of the first and second pieces, complying with the necessary transportation regulations. The overall size of the multi-piece chamber violates at least one of ground or air transport regulations.

In certain embodiments of the present invention, a method of transporting a multi piece chamber having a center piece, a first side piece and a second side piece is provided. The method includes (1) placing at least a portion of the vacuum robot within the central piece of the chamber; (2) transporting the central piece via either ground or air transport; (3) joining the first side piece to the second side piece; (4) transporting the first and second side pieces together via either ground or air transport; And (5) during transportation of the central piece, the first and second pieces, complying with the necessary transportation regulations. The overall size of the multi-piece chamber violates at least one of ground or air transport regulations.

In certain embodiments of the present invention, (1) coupling the electronic device manufacturing chamber to one or more sliding mechanisms of the electronic device manufacturing chamber support; And (2) using one or more sliding mechanisms to accommodate the electronic device manufacturing chamber expansion, thereby ensuring that the electronic device manufacturing chamber does not leave its position on the electronic device manufacturing chamber support. This is provided.

In certain embodiments of the present invention, an apparatus for supporting an electronic device manufacturing chamber is provided. The apparatus includes (1) one or more support members; And (2) a base frame comprising one or more sliding mechanisms. One or more sliding mechanisms are coupled to the electronics manufacturing chamber to accommodate the electronics manufacturing chamber expansion, such that the multi-piece electronics manufacturing chamber does not leave the position on the base frame.

In a particular embodiment of the present invention, (1) a central piece of a multi piece chamber coupled to the first side piece and the second side piece to form a multi piece chamber; (2) a vacuum robot disposed in the center piece of the chamber; (3) An apparatus is provided comprising a unit having a base frame for a center piece coupled with the center piece. The size of the unit follows at least one of the ground or air transport regulations.

In certain embodiments of the present invention, (1) a first side piece of a multi piece chamber; And (2) a unit having a second side piece of the multi piece chamber. The first and second side pieces are coupled to the central piece to form a multi piece chamber. The unit includes (1) a first base frame coupled to the first side piece; And (2) a second base frame coupled to the second side piece. The size of the unit follows at least one of the ground or air transport regulations. Many other aspects are provided according to these or other aspects of the present invention. Other features and aspects of the present invention will become more fully apparent from the following detailed description, the appended claims, and the accompanying drawings.

Regarding the central transfer chamber, machining the "on-site" central transfer chamber from a single aluminum block and disassembling the central transfer chamber into multiple elements are discussed as possible approaches for scaling of the transfer chamber. come. See, for example, "LCD Large-Area Substrate Issues, Substrate Enlargement: Where is the Size Limitation?", Flat Panel Display 2003 (Panel Discussion), where I. D. Kang of Applied Komatsu Corporation Technology (AKT) states:

If the transfer chamber is larger, one alternative to the installation is for a single aluminum block to be machined in Asia. Another way is to disassemble the central transfer chamber into a number of elements. Although machining the chamber from a single block of aluminum meets the vacuum conditions, it is possible to build and field assembly a large transfer chamber made of elements composed of several aluminum blocks.

A first aspect of the method and apparatus relates to a method and apparatus for meeting the size of a large electronic device manufacturing chamber, such as a transfer chamber. A second aspect of the present method and apparatus relates to a method and apparatus for dynamically supporting an electronic device manufacturing chamber.

Electronic device manufacturing chamber

1 is a top view of a first exemplary multi piece electronic device manufacturing chamber in accordance with some embodiments of the present invention. Referring to FIG. 1, the multi-piece electronic device manufacturing chamber 101 is a transfer chamber for transferring a substrate while manufacturing an electronic device. The transfer chamber is coupled with one or more process chambers and / or load locks 103 during manufacturing of the electronic device. The transfer chamber includes an end effector 105 for transporting the substrate 107 in the process chamber and / or load lock 103 during the manufacture of the electronic device. The substrate 107 may include, for example, a glass plate, a polymer substrate, a semiconductor wafer, or the like.

According to some embodiments of the present invention, the transfer chamber 101 comprises multiple pieces coupled to each other. More specifically, the transfer chamber 101 includes a first piece 109 (eg, a first side piece) and a second piece 111 (eg, a second side piece) coupled to a third piece (eg, a center piece). ) May be included. The first piece 109 and the second piece 111 may each be coupled to the third piece 113 via an O-ring (not shown separately). The first piece 109 and the second piece 111 are respectively fixed to the third piece 113 using fixing means such as screws, bolts, and the like. Although the multi-piece electronics manufacturing chamber 101 of FIG. 1 includes three pieces, the multi-piece electronics manufacturing chamber 101 includes more or fewer pieces (eg, 2, 4, 5, 6, etc.). can do.

The width of existing transfer chambers (eg, single piece transfer chambers) is generally limited to about 3 m or less by ground and / or air transport regulations, transport capacity or drying design. For example, transfer chambers larger than 3 m may be prohibited from being transported by the most common 747 cargo planes by local regulations and may be too large to fit the entrance of a standard electronics manufacturing facility. In comparison, in one embodiment of the present invention, the width W1 of the multi-piece transfer chamber is 4.2m when assembled (ie, full width). Thus, the electronic device manufacturing chamber 101 can accommodate a larger substrate than a conventional single piece transfer chamber. The width of the electronic device manufacturing chamber 101 may be larger or smaller than 4.2m.

The shape (eg, overall shape) of the exemplary multi piece electronic device manufacturing chamber 101 is hexagon when assembled. However, the multi-piece electronics manufacturing chamber 101 is octagonal in other overall shapes (e.g., if eight chambers are coupled to the transfer chamber 101), and the first and second pieces 109, 111 are triangular as shown. Rather than trapezoidal in shape).

2A is an exploded perspective view of a first exemplary multi piece electronic device manufacturing chamber in accordance with some embodiments of the present invention. Each of the first to third pieces 109 to 113 is horizontally coupled to form a multi-piece electronic device manufacturing chamber 101. The length of the first piece 109 is denoted LS1 and the width of the first piece 109 is denoted WS1. The length of the second piece 111 is indicated by LS2 and the width of the second piece 111 is indicated by WS2. The length of the third piece 113 is denoted LC1 and the width of the third piece 113 is denoted WC1.

In one or more embodiments, the width WC1 of the third piece 113 is about 2.4 m and the length LC1 of the third piece 113 is 4.2 m. Larger or less length and / or width may be employed in the third piece 113. In the illustrated embodiment, the length LC1 of the third piece 113 is the full width W1 of the chamber 101. As shown, the length LS1 of the first piece 109 and the length LS2 of the second piece 111 are equal to the length LC1 of the third piece 113. However, the length LS1 of the first piece 109 and / or the length LS2 of the second piece 111 may be different. In one embodiment, the width WS1 of the first piece 109 and / or the width WS2 of the second piece 111 is about 1.2 m. However, the width WS1 of the first piece 109 and / or the width WS2 of the second piece 111 may be different (eg, larger or smaller). (In one specific embodiment, the first and second pieces 113 may have a width that is approximately equal to or less than the width of the first piece 109 plus the width of the second piece 111. And a relationship between the widths of the third pieces 109, 111, and 113 may be employed.) Each piece 109-113 of the multi-piece electronic device manufacturing chamber 101 may be, for example, aluminum, stainless steel or the like. It can be made of any practical and relatively inert material suitable for use as a transfer chamber.

Although the overall size of the multi-piece electronics manufacturing chamber 101 does not comply with ground and / or airborne regulations, the size of each piece 109-113 of the multi-piece electronics manufacturing chamber 101 may be over ground and / or airborne. Follow the rules. More specifically, in the above example, the overall width W1 of the multi-piece electronic device manufacturing chamber 101 is 4.2 m, which does not follow the ground and / or air transport regulations. However, the width WS1 of the first piece 109 and the width WS2 of the second piece 111 are 1.2 m and the width WC1 of the third piece 113 is 2.4 m and each of these follows ground and / or air transport regulations. (In another embodiment, the width WC1 of the third piece 113 may be about 3 to 3.2 m and the widths WS1, WS2 of the first and second pieces 109, 111 may be about 1.5 to 1.6 m. .)

Furthermore, each piece 109-113 of the multi piece electronic device manufacturing chamber 101 can be manufactured in an existing machine center or shop. Thus, a manufacturer of a multi piece electronic device manufacturing chamber 101 may select one or more existing machine centers or shops to fabricate the pieces 109-113 of the multi piece electronic device manufacturing chamber 101. Competition between multiple existing machine centers or shops allows manufacturers of multi-piece electronic device manufacturing chambers 101 to obtain better prices. In contrast, the number of machine centers or shops that can manufacture single piece electronic device manufacturing chambers that can accommodate larger substrates similar to the multi piece electronic device manufacturing chamber 101 is limited. This limited number of machine centers or shops results in reduced competition. Because of the reduced competition, manufacturers may have to pay more for manufacturing single piece electronic device manufacturing chambers than for manufacturing multi piece electronic device manufacturing chamber 101. Furthermore, such single piece chambers do not comply with ground and / or air transport regulations, so that manufacturers of such single pieces can obtain special accommodations such as police guards, "Oversized Load" signs, etc. during transportation. There may be a need. The multi piece electronic device manufacturing chamber 101 does not need such a convenience.

Additional features of the first multi-piece electronic device manufacturing chamber 101 will be described with reference to FIGS. 2B-2D as well as to FIG. 2A, which is a perspective view of the first chamber 101 at the time of assembly, and FIG. 2C Is a plan view of the first chamber, and FIG. 2D is a side view of the first chamber (showing the facets of the first chamber 101 coupled to the triple substrate stacked load lock chamber described below).

Referring to FIGS. 2A and 2B, the first chamber 101 includes a plurality of facets 201a-201f (FIG. 2C). In the illustrated embodiment, more or fewer facets may be provided (as described above), but six facets have been presented.

Each facet 201a-201f is configured such that, for example, the process chamber, load lock chamber, or other chamber is sealed (eg, an O-ring or other sealing member) as shown in relation to chamber 103 in FIG. 1. Through) to provide a flat sidewall. Despite the presence of facets 201a-201f, the overall structure of the first chamber 101 is substantially cylindrical. For example, as shown in FIGS. 2A-2C, the first (side) piece 109 includes a cylindrical wall 203 on which facets 201b and 201c are formed, and the second (side) piece 111 ) Includes a cylindrical wall 205 in which facets 201e and 201f are formed. The third (center) piece 113 has substantially flat opposing sidewalls 207 and 209 that act as facets 201a and 201d, respectively, as shown (FIG. 2A).

Because of the cylindrical walls 203, 205 of the first and second pieces 109, 111, the interior region of the first chamber 101 is substantially cylindrical (see, eg, FIGS. 2A and 2C). The cylindrical configuration reduces the internal volume of the first chamber 101 and allows free rotation of the vacuum robot (FIG. 7) disposed within the first chamber 101. Such rotation may occur, for example, at the time of rotation for the robot to transfer the substrate between the various chambers coupled to the first chamber 101 (FIG. 1).

In order to accommodate the rotation of the vacuum robot through the third (center) piece 113 of the chamber 101, the third piece 113 shows only the notch regions 211a to 211d (notches 211a to 211c in FIG. 2a). It is included. Notches 211a through 211d may also provide additional clearance while the substrate is being transported through openings (eg, slit openings) formed in each facet of first and second side pieces 109 and 111. Notches 211a-211d (as shown in FIGS. 2A and 2B) are transported through the openings 213, 215, 217, 219 corresponding to facets 201f, 201e, 201c, 210b, respectively. It can provide additional free space.

Although facets 201b, 201c, 201e, 201f are shown having only one opening, each facet may include additional openings (eg, 2, 3, 4, or more). Similarly, facet 201a of third (center) piece 113 (in FIG. 2A) is shown as having a single opening 221, but includes additional openings (eg, 2, 3, 4, etc.). can do. Facets 201d of third piece 113 (in FIGS. 2A and 2C) include three vertically stacked openings 223a through 223c, but with a different number of openings (eg, 1, 2, 4, 5). And the like). In at least one embodiment of the present invention, the bottom opening 223c of the facet 201d of the third (center) piece 113 (as shown in FIG. 2D) is the facet 201e of the second side piece 111. And an opening 215 of the facet 201c of the first side piece 109. Each opening 213-223c is sized to allow the substrate to pass therethrough. Other configurations may be employed.

2A-2C, the first and second side pieces 109, 111 include a plurality of fin structures 225, each of which imparts structural integrity to the first chamber 101. do. For example, the fin structure 225 may be formed by the first and second side pieces 109 due to the pressure difference between the first chamber 101 and any process chambers coupled thereto and / or the external environment of the first chamber 101. Deflection of the cylindrical sidewalls / topwalls of 111) can be reduced. Further, the use of the fin structure 225 reduces the wall thickness of the first and second pieces 109, 111 to reduce the overall weight of the first chamber 101. In one embodiment, the fin structure 225 has a thickness of about 0.55 inches near the outer sidewalls / top walls of the first and second side pieces 109, 111, and the first and first portions connected with the central piece 113. Near the sealing surface of the two side pieces 109, 111, having a thickness of about 1.3 inches (for stainless steel), other materials and / or thicknesses may be used.

As further shown in FIG. 2A, the bottom 227 of the third (center) piece 113 of the first chamber 101 includes a flat portion 229 and a domed portion 231 (also shown in FIG. 2D). ). Because of the domed shape, the domed portion 231 improves the strength of the bottom 227, thus reducing the thickness requirement of the bottom 227 material. In one exemplary embodiment, the domed portion 231 may have a thickness of about 3/8 inch or less, whereas the flat portion 227 may have a thickness of about 3/4 to 1 inch. It may be less than when using stainless steel. Other materials and / or thickness values and / or thickness differences between the flat portion 229 and the domed portion 231 may be used. To further increase the strength of the domed portion 231, a pin or similar support 233 may be formed below the domed portion 231 as shown in FIG. 2D. The use of the pin 233 can, for example, reduce the vertical warp of the domed portion 231.

2B-2C and 8 show a top cover 235 that can be employed with the first chamber 101. For example, the lid 235 can seal the third (center) piece 113 of the first chamber (by employing an O-ring or similar sealing element between the lid 235 and the third piece 113).

2B-2C and 8, the top cover 235 includes a flat sealing portion 237 reinforced with a plurality of supports, such as the beam 239 shown. Seal portion 237 may be similar in thickness to flat portion 229 (FIG. 2A) of lower portion 227 of chamber 101, and beam 239 may allow the thickness and weight of lid 235 to be reduced. ) Provide additional structural support. The lid 235 can include a connection location 241 that can be used to lift and / or lower the lid 235 with respect to the first chamber 101 (eg, via a crane or the like).

Due to the weight of the lid 235, the entire lid 235 to provide another opening within the lid 235 or one or more access hatches (eg, for equipment maintenance or repair) to access inside the first chamber 101. It may be desirable to eliminate the need to remove from the chamber 101. 2E is a perspective view of the first chamber 101 employing another cover design 235 'comprising two access hatches 234a and 234b. Each access hatch 234a, 234b may be opened such that the entire lid 235 ′ can be accessed to an interior region of the first chamber 101 without having to be removed from the first chamber 101. Other numbers of access hatches (eg, 1, 3, 4, etc.) can be used.

3 is a perspective view of a second exemplary multi piece electronic device manufacturing chamber 301 in accordance with some embodiments of the present invention. The second exemplary multi piece electronic device manufacturing chamber 301 includes first to fifth pieces 303 to 311 coupled to each other. However, the second exemplary multi piece electronic device manufacturing chamber 301 may include more or fewer pieces. Compared to the first exemplary multi piece electronic device manufacturing chamber 101, each piece of the second exemplary multi piece electronic device manufacturing chamber 301 is vertically coupled to form a second multi piece electronic device manufacturing chamber 301. can do.

4 is an exploded perspective view of a second exemplary multi-piece electronic device manufacturing chamber 301 in accordance with some embodiments of the present invention. The first piece 303 of the second exemplary multi piece electronic device manufacturing chamber 301 is a domed top cover. The diameter D1 of the domed top cover 303 may be, for example, about 4.2 m. The domed top cover 303 may be made of stainless steel or other materials, which may be manufactured using spinning or other techniques.

The domed top lead 303 is coupled with the second piece 305, the second piece 305 to the third piece 307, and the third piece 307 to the second exemplary multi-piece electronics manufacturing chamber. Is coupled to the fourth piece 309 of 301. The second to fourth pieces 305-309 of the second exemplary multi piece electronic device manufacturing chamber 301 form the main body of the second exemplary multi piece electronic device manufacturing chamber 301. Each of the widths W2 from the second to fourth pieces 305-309 may be, for example, about 4.2 m. Each of the widths of the second 305, third 307 and / or fourth piece 309 may be different and each of the second to fourth pieces 305-309 is shown in a hexagonal shape, although other shapes This can be adopted. In one embodiment, each of the second to fourth pieces 305-309 is aluminum, although other materials may be used. In addition, a single piece may be employed as the main body.

The fifth piece 311 is a domed bottom cover for the second exemplary multi piece electronic device manufacturing chamber 301. The fifth piece 311 is coupled to the bottom of the fourth piece 309. Similar to the domed top lid, the diameter D2 of the domed bottom cover can be, for example, about 4.2 m. Other sizes can be used.

In order to manufacture the multi-piece electronic device manufacturing chambers 101 and 301, a user, such as a manufacturer, may employ the patent method described below. According to the patented method, one or more overall sizes of the electronic device manufacturing chambers are determined. More specifically, the manufacturer needs to manufacture a substrate of the required size. Based on the size required, a manufacturer can determine one or more overall sizes (eg, designs) of an electronic device manufacturing chamber that can manufacture such a substrate. If the required substrate size is large enough, the overall size of the chamber will not follow at least one of ground or air transport regulations.

Thus, for example, a manufacturer may have established an electrical equipment manufacturing chamber such that when the size of each of the plurality of pieces is assembled at the same time while meeting at least one of the ground or air transport regulations, the structural integrity of the chamber is sufficient to perform the manufacturing process. You can decide how to divide into multiples. For example, a manufacturer may use vertical sectioning, such as the electronic device manufacturing chamber 101 shown in FIGS. 1-2, or horizontal sectioning, such as the electronic device manufacturing chamber 301 shown in FIGS. Multi-piece electronics fabrication chambers designed using them can be divided into pieces. The manufacturer may decide to divide the electronic device manufacturing chamber into pieces using a split having a different direction or combination of directions.

Thus, a plurality of pieces are manufactured. For example, a manufacturer may employ a machine center or shop to manufacture a plurality of pieces. In this manner, the multi piece electronic device manufacturing chambers 101 and 301 are manufactured.

Once the electronic device manufacturing chambers 101, 301 are manufactured, the electronic device manufacturing chambers 101, 301 can be shipped, for example, to a customer site. To transport the multi-piece electronic device manufacturing chambers 101 and 301, a manufacturer may employ a method for transporting such chambers in accordance with one or more embodiments of the present invention. For example, the first piece of the plurality of electronic device manufacturing chamber pieces can be transported via either ground or air transport. The first piece may be placed in a container that conforms to shipping regulations such that the first piece forms an angle with respect to the side (such as the bottom side) of the container. Thus, if the first piece is not placed in the container at such an angle, it may have a larger actual height or width than allowed but still fit within the container following ground or air transport regulations. The ability to transport larger pieces allows the multi piece chamber of the present invention to be formed from fewer pieces. So, even if not needed, it is preferred to place the pieces at an angle in the shipping container. In some embodiments, it may be desirable to fabricate a multi piece chamber so that the main or center piece fits as large and still fits within a standard size shipping container and the remaining pieces are smaller or as small as possible to facilitate assembly.

5 is a first piece of a second exemplary multi piece electronic device manufacturing chamber in container 501, in accordance with some embodiments of the present invention. Referring to FIG. 5, the width W3 of the container 501 may be, for example, 3m following most ground or air transport regulations. Smaller containers can be used. The first piece 303 (eg, domed top cover) is disposed within the container 501 such that the first piece 303 forms an angle A of about 50 degrees with the face 503 (eg, bottom) of the container 501. Can be. The first piece 303 may form a larger or smaller angle with the face 503 of the container 501. In one embodiment, the first piece 303 forms an angle A of 50 degrees or more and 90 degrees or less with the face 503 of the container 501. As a result, even though the width of the first piece 303 is 4.2 m, the first piece 303 fits a smaller width container. Thus, the container 501 is transported via ground or air transport. In this way, the transport regulations required during the transport of the first piece are followed.

Similarly, the second piece 305 of the electronic device manufacturing chamber 301 is transported via either ground or air transport. The second piece 305 forms an angle with the bottom face of the container so that the second piece is placed in a container that conforms to shipping regulations. For example, FIG. 6 is a side view of a second piece 305 of a second exemplary multi piece electronic device manufacturing chamber 301 in a container 501, in accordance with at least one embodiment of the present invention. Referring to FIG. 6, the second piece 305 is disposed in the container 501 in a similar manner as the first piece 303.

The overall size of the assembled multi-piece electronic device manufacturing chamber 301 violates at least one of ground or air transport regulations. For example, the overall width of the multi-piece electronics manufacturing chamber 301 is not less than 3 m, which does not comply with ground and / or air transport regulations. Thus, the first and / or second pieces are separated and transported, for example, to container 501.

In this way, the multi piece electronic device manufacturing chambers 101 and 301 can be manufactured without the disadvantages (eg, cost) of manufacturing a similar size single piece electronic device manufacturing chamber in a machine center or shop. Further, the multi piece electronic device manufacturing chambers 101 and 301 can be shipped to a purchaser's location without the disadvantages (eg, cost, time, etc.) of manufacturing a single piece electronic device manufacturing chamber of similar size.

Electronic device manufacturing Of chamber  support

7 is a perspective view of an electronic device manufacturing chamber support 701 according to the present invention. Referring to FIG. 7, the electronic device manufacturing chamber support 701 includes a base frame 703. One or more portions of the base frame 703 may be attached to the floor (eg, in a manner to secure through the floor anchor 704).

In an existing manufacturing chamber support, one or more portions of the base are (eg fixedly) attached to the bottom of the electronic device manufacturing chamber. Compared to existing fabrication chamber supports, electronic device fabrication chamber supports 701, in accordance with some embodiments of the present invention, additionally or alternatively include one or more sliding mechanisms 705 to facilitate the fabrication of electronic device fabrication chamber 709. Dynamic support may be provided to the floor 707. One or more sliding mechanisms 705 may include elastomeric mounts that include slidable bearings, such as polytetraflouoroethylene (PTFE) coated bearings, rod bearing rubber, and the like. Other suitable materials may be used for one or more sliding mechanisms 705.

Instead of this, the one or more sliding mechanisms 705 may include rollers instead of or in addition to the sliding bearings. In some embodiments, electronic device manufacturing chamber 709 is suspended with vertical, diagonal and / or horizontal flexible lines such that any expansion has an expansion capability that exceeds the maximum expansion capability of electronic device manufacturing chamber 709. Can be accommodated by the elastic line.

One or more sliding mechanisms 705 accommodate thermal or other expansion of the electronic device manufacturing chamber 709. For example, during electronic device manufacturing, heat from adjacent process chambers may cause the temperature of electronic device manufacturing chambers 101, 301 to exceed 200 or 300 degrees Celsius, which expands electronic device manufacturing chamber 709. The sliding mechanism 705 prevents the electronic device manufacturing chamber 709 from moving out of position on the electronic device manufacturing chamber support 701 (eg, on the base frame 703). The sliding mechanism 705 is effective to accommodate any possible amount of electronic device manufacturing chamber expansion, such that the electronic device manufacturing chamber 709 moves slightly off the electronic device manufacturing chamber support 701 or even positions it. To prevent deviations from

8 is a perspective view of an exemplary electronic device manufacturing chamber support 801 in accordance with some embodiments of the present invention. Referring to FIG. 8, an example electronic device manufacturing chamber support 801 may be a multi piece support. More specifically, the example electronic device manufacturing chamber support 801 can include a multi piece base frame 803. For example, the base frame 803 may include a first piece 805, a second piece 807, and a third piece 809. Base frame 803 may include larger or fewer pieces. Pieces of the example electronic device manufacturing chamber support 801 may correspond to pieces (eg, 109-113) of the multi-piece electronic device manufacturing chamber 101 supported by the example electronic device manufacturing chamber support 801. Can be.

In the example shown in FIG. 8, the third piece 809 (eg, center piece) of the base frame 803 includes eight sliding mechanisms 705. The third piece 809 can include a larger or fewer sliding mechanism 705. As shown in FIG. 7, one or more sliding mechanism 705 may be aligned with (eg, directly above) the floor anchor 704. However, the sliding mechanism 705 may be arranged differently. Similarly, the first and second pieces 805, 807 of the base frame 803 may include a plurality of sliding mechanisms 705. While the multi-piece electronic device manufacturing chamber support 801 has been described above, the example electronic device manufacturing chamber support 801 may be a single piece support.

When thermal expansion causes one or more sliding mechanisms 705 to reach the edges of their respective ranges, in some embodiments other sliding mechanisms 705 will begin receiving any additional thermal expansion that was directed to the original sliding mechanism 705. In other words, when the force applied to move the sliding mechanism 705 to the limit of the individual range reaches a stop frame (to be described later), the inflation force is reversed in the opposite direction by the other sliding mechanism 705. Can be accommodated.

9 is an enlarged perspective view of a detail of an exemplary electronic device manufacturing chamber support 801, in accordance with some embodiments of the present invention. Referring to FIG. 9, an example electronic device manufacturing chamber support 801 includes one or more sliding mechanism 705, which can include a sliding bearing 905 and an elastomeric mount 907.

Sliding bearing 905 may include a shaft or threaded rod 903 attached to foot or slip disk 901. Slip disk 901 is, for example, may be in the coating of a low friction fluoropolymer (fluoropolymer) resin such as Teflon ^® manufactured by DuPont recess (recess) (904). The recess or “stop frame” 904 may be square or round or any suitable shape to accommodate the desired range of horizontal movement of the slip disk 901. In the same manner, the slip disk 901 may be square or round or any suitable shape to accommodate the desired range of horizontal movement in the recess 904. Slide bearing 905 may be made of steel or any suitable material. A lower portion and a side surface in some embodiments, the slip discs 901 may be able to move freely within the be coated with a low friction fluoropolymer resin slide bearings 905, the recess 904, such as Teflon ^® . Further, the slip disk 901 may include rollers or ball bearings instead of or in addition to the low friction coating. In some embodiments, any suitable movable bearing can be used in place of the sliding bearing 905.

A shaft or threaded rod 903 attached to the slip disk 901 may also be attached to the bottom 707 (FIG. 7) of the electronic device manufacturing chamber 709. Threaded rod 903 may be secured into a threaded recess in bottom 707 of electronics manufacturing chamber 709 or may be attached using any suitable clamping device, such as a pin or other fastener.

Elastomer mount 907 may comprise a stretchable material, such as rod bearing vulcanized rubber, sandwiched between and attached to mounting plates 908a through 908b. Other suitable stretchable materials including metal springs can be used. The mounting plate may be made of steel or other suitable material, and holes that allow the mounting plate to be attached to the bottom 707 of the electronics manufacturing chamber 709 and the bracket 909 portion of the base frame 803, respectively. It may include.

In operation, the slide bearing 905 can transfer the weight of the electronic device manufacturing chamber 709 and also allow the electronic device manufacturing chamber 709 to move within an acceptable range upon expansion. At the same time, the elastomer mount 907 operates such that the electronic device manufacturing chamber 709 is effectively deflected toward an ideal position on the electronic device manufacturing chamber support 801. As described above, the allowable range of movement of the electronic device manufacturing chamber 709 may be defined by the size of the slip disk 901 and the recess 904 on which it is seated. The location and geometry of the recess can also affect the range of motion. In some embodiments, elastomer mount 907 may additionally or instead define a range of motion of electronic device manufacturing chamber 709.

To further describe the subject innovation, exemplary sizes are provided. However, the following sizes are merely illustrations of specific embodiments and are merely intended to convey examples of suitable relative sizes. In some embodiments, the diameter D3 of the slip disk 901 is about 100 mm, the recess 904 is about 125 mm diagonal, the height h1 of the slip disk 901 is about 25 mm, and the shaft or threaded rod 903 Diameter D4 is about 25 mm, and the threaded rod 903 height h2 is about 137 mm. In some embodiments, an M25 bolt (ISO 965-1, Sect. 5, metric fastener size designation) may be used as the threaded rod 903. The sliding mechanism 705 can be of a different shape and / or size than shown. In some embodiments, elastomeric mount 907 may be curved or stretched to about 15 mm. Elastomeric mount 907 may be shaped and / or sized other than shown.

10 is a perspective view of the example electronic device manufacturing chamber support 801 of FIG. 9 shown to support the electronic device manufacturing chamber 101. Referring to FIG. 10, a sliding bearing 905 and an elastomer mount 907 of each support 801 are coupled to the bottom of the electronic device manufacturing chamber 101.

During manufacturing of the electronic device, the electronic device manufacturing chamber 101 may be grown by thermal expansion or other force. More specifically, a portion of the electronic device manufacturing chamber 101 on the support 801 may expand in both vertical and horizontal directions. Stretching or expanding the electronic device manufacturing chamber 101 compresses or stretches the elastomeric mount 907 and moves the sliding bearing 905. In this manner, each sliding mechanism 705 receives the bending or stretching of any expanded portion of the electronic device manufacturing chamber 101. The remaining sliding mechanism 705 is also used to accommodate the electronic device manufacturing chamber expansion in a similar manner, thereby preventing the electronic device manufacturing chamber 101 from deviating from its position on the electronic device manufacturing chamber support 801. In this manner, the electronic device manufacturing chamber 101 remains substantially balanced and horizontal during manufacturing of the electronic device. In comparison, thermal expansion of a manufacturing chamber supported by an existing support can cause the electronic device manufacturing chamber to deviate from the position of the support, to fall off and / or to damage the support.

For support of the electronic device manufacturing chamber, according to some embodiments of the present invention, a method for supporting the electronic device manufacturing chamber may be adopted. More specifically, the electronic device manufacturing chamber is coupled to one or more sliding mechanisms 705 of the electronic device manufacturing chamber support 801. One or more sliding mechanisms 705 are adapted to accommodate electronic device manufacturing chamber expansion, thereby preventing the electronic device manufacturing chamber from being out of position or falling from the electronic device manufacturing chamber support 801. For example, the elastomeric mount 907 of the sliding mechanism 705 can be stretched or compressed to accommodate electronic device manufacturing chamber compression.

The following description merely discloses an exemplary embodiment of the present invention. Modifications of the above disclosed apparatus and methods within the scope of the present invention will be apparent to those skilled in the art. For example, although some embodiments described above relate to transfer chambers, the present security and apparatus may also be employed with respect to other types of electronic device manufacturing chambers, such as process chambers for PVD, CVD. Furthermore, in one or more embodiments, the robot may be inserted (eg assembled) prior to shipping to the purchaser's location as a piece of multi-piece electronics manufacturing chamber 101, 301. For example, the bottom portion of the vacuum robot can be installed in the third (center) piece 809 (FIG. 8) of the frame 803, such as in the base ring 811 of the frame 803, and the upper portion of the vacuum robot. Silver may be installed in the third (center) piece 113 of the chamber 101. The third portion 113 of the chamber 101 may be coupled to the third piece 809 of the base frame 803, and the base frame / center chamber piece assembly may be transported to the unit. 11 is a perspective view of an exemplary base frame / center chamber piece assembly 1101 that may include a vacuum robot (not shown) and is ready for transportation. In at least one embodiment, cover units 1103a and 1103b are installed on the open side of the third (center) piece 113 of the chamber 101 before shipping. The cover unit 1105 is installed over the opening of any facet of the third piece 113. Cover units 1103a and 1103b and 1105 may be formed of aluminum or any other suitable material and may protect any components installed inside and / or inside chamber 101 during shipping.

In one or more embodiments of the present invention, assembly 1101 is sized according to at least one of ground or air transport regulations. For example, assembly 1101 may have a height of about 3 m or less.

In another embodiment of the present invention, the first and second side chamber pieces 109, 111 and the first and second base frame pieces 807, 805 may be assembled and / or transported together in a unit. For example, FIG. 12 is a perspective view of a side piece / base frame assembly 1201 that may be transported to a unit. For example, the first side piece 109 of the chamber 101 is coupled to the base frame piece 807, the second side piece 111 of the chamber 101 is coupled to the base frame piece 805, and the side piece By arranging the / base frame assemblies together as shown, assembly 1201 can be formed. The assembly 1201 can then be shipped to the unit. Cover unit 1203, similar to cover unit 1105 of FIG. 11, may be used to cover any facet opening (eg, to protect the interior of the chamber piece) prior to shipping.

In one or more embodiments of the present invention, assembly 1201 is sized according to at least one of ground or air transport regulations. For example, assembly 1201 may have a height of about 3 m or less.

The pieces of chambers 101 and 103 and / or of the base frame 803 may be transported using any suitable method. In at least one embodiment, the side pieces 109, 111 of the chamber 101 may be transported using a first mode of transport (eg, overland, ship, air, etc.) and the central piece 113 of the chamber 101. ) May be transported using a second mode of transport (eg, land, ship, air, etc.). As another example, the first and / or second side pieces 109, 111 may be transported through a first truck, and the center piece 113 may be transported using a second truck.

In at least one embodiment of the present invention, in a manner similar to that described in US patent application Ser. No. 10 / 601,185, filed Jun. 20, 2003, which is incorporated herein by reference, the vacuum robot is a floating sealing. Can be used to isolate the robot from the movement of the chamber bottom shown in FIG. 7 (eg, by raising the robot onto the chamber's frame using a bellows seal).

As shown in FIGS. 2A-2E, the side pieces 109, 111 of the first chamber 101 are each single piece units that do not require a separate cover or bottom. Separate covers and / or bottoms may be employed for one or both of the side pieces 109, 111, but may require additional sealing interfaces that may degrade and / or leak.

While the present invention has been primarily described with respect to flat panel displays, the present invention provides that multi-piece electronic device manufacturing chambers can be used for the transport, processing and / or manufacture of any type of substrate, and that any type of device (eg, flat panel display, solar It can be used for the transfer, processing and / or manufacture of panels and / or batteries, etc.)

It may be appreciated that shipping regulations may vary from country to country (eg, US, Japan, Korea, Taiwan, China, etc.). For example, size restrictions or other related transport parameters may vary from country to country. However, the present invention may be adapted / modified (still within the spirit and scope of the present invention) to accommodate certain shipping regulations in any country.

Thus, while the present invention has been disclosed in connection with exemplary embodiments, it is to be understood that other embodiments are within the spirit and scope of the invention as defined by the appended claims.

The device and method facilitate the fabrication, transportation, and support of large electronic device manufacturing chambers.

Claims (67)

A central piece comprising a first side and a second side; A first side piece coupled to the first side of the center piece; And A second side piece coupled to the second side of the center piece, wherein the center piece, the first side piece and the second side piece, when joined together, form a substantially cylindrical inner chamber region; Multi-piece chamber comprising a. The method of claim 1, And the center piece, the first side piece and the second side piece, when joined together, form a transfer chamber. The method of claim 1, The central piece has a substantially rectangular shape. The method of claim 1, The central piece has a length of about 3 m or more. The method of claim 4, wherein The central piece has a width of about 2.4 m or more. The method of claim 1, Wherein said central piece comprises a bottom having a domed portion. The method of claim 6, The domed portion is a multi piece chamber for receiving a vacuum robot. The method of claim 6, The domed portion includes at least one support fin to reduce movement of the domed portion in the vertical direction. The method of claim 8, The domed portion comprises a plurality of support fins, each support pin reducing the movement of the domed portion in the vertical direction. The method of claim 6, The bottom of the center piece comprises a flat portion. The method of claim 10, Wherein said flat portion has a first thickness and said domed portion has a second thickness less than said first thickness. The method of claim 11, Wherein the first thickness is about 0.75 to 1 inch or less and the second thickness is about 0.375 inch or less. The method of claim 11, Wherein the flat portion and the domed portion are formed of stainless steel. The method of claim 1, The central piece comprises a first facet and a second facet, The first facet includes at least one opening and is sized to allow a substrate to pass through the opening, The second facet includes at least two openings, each of which is sized to allow a substrate to pass through the opening. The method of claim 14, The second facet comprises at least three openings, each sized to allow a substrate to pass through the opening. The method of claim 14, And the first facet is coupled to a processing chamber in a sealingly sealed manner. The method of claim 16, And the second facet is coupled to the load lock chamber to be sealed. The method of claim 17, The second facet is sealedly coupled to a load lock chamber that stores at least three substrates stacked vertically. A first opening sized to allow a substrate to pass between the center piece and the load lock chamber at a first height; A second opening sized to allow a substrate to pass between the center piece and the load lock chamber at a second height; And A third opening sized to allow a substrate to pass between the center piece and the load lock chamber at a third height Multi-piece chamber comprising a. The method of claim 18, The first side piece comprises at least one first facet including the opening that is sized to allow a substrate to pass through the opening; The second side piece comprises at least one first facet comprising the opening sized to allow a substrate to pass through the opening; And When the first side piece, the second side piece and the center piece are joined together, the opening of the first facet of the first side piece, the opening of the first facet of the second side piece and the first of the center piece And the first opening of the two facets is substantially the same height. The method of claim 1, The first side of the center piece is at least one agent that allows the substrate to be rotatable within the multi piece chamber while the substrate is transferable from the multi piece chamber to a chamber coupled to the first side piece of the multi piece chamber. 1 notch Multi-piece chamber comprising a. The method of claim 20, At least one first side of the central piece allows the substrate to be transferred from the multi piece chamber to a chamber coupled to the second side piece of the multi piece chamber while the substrate is rotatable within the multi piece chamber. Notch Multi-piece chamber comprising a. The method of claim 1, Wherein the first side piece and the second side piece have a first width, and wherein the central piece has a second width that is at least about twice the first width. The method of claim 1, Wherein the first side piece comprises a substantially cylindrical side wall and has a plurality of flat facets formed in the side wall. The method of claim 23, wherein Wherein said first side piece comprises two facets, each facet including an opening such that a substrate is sized to pass through said opening. The method of claim 23, wherein The first side piece includes at least one fin structure to reduce movement of the sidewall of the first side piece. The method of claim 25, The first side piece includes a plurality of fin structures that reduce movement of the sidewalls of the first side piece. The method of claim 1, And the second side piece comprises a substantially cylindrical sidewall and has a plurality of flat facets formed in the sidewall. The method of claim 1, And a cover covering at least the central piece. The method of claim 28, The cover includes a flat portion and a plurality of support beams to reduce movement of the flat portion in a vertical direction. The method of claim 29, Wherein the flat portion has a thickness that is about 0.75 to 1 inch or less. The method of claim 29, The cover includes at least one hatch, allowing access to an interior region of the multi piece chamber without having to remove the cover. The method of claim 31, wherein Wherein the cover includes at least two hatches, each hatch providing access to an interior region of the multi piece chamber without having to remove the cover. A first open side; A second open side opposite the first open side; A first facet between the first open side and the second open side, the first facet including an opening coupled to the chamber and sized for the substrate to pass through; And A second facet facing said first facet, said second facet between said first open side and said second open side, said second facet comprising at least two openings coupled to the chamber and stacked vertically, each opening having a substrate; Is the size through which A central piece comprising a; A first side piece coupled to the first open side of the central piece, the first side piece including at least one first facet comprising an opening of a size through which the substrate can pass; And A second side piece coupled to a second open side of the central piece, the second side piece including at least one first facet comprising an opening of a size through which the substrate can pass; When the first side piece, the second side piece and the center piece are joined together, the opening of the first facet of the first side piece, the opening of the first facet of the second side piece and the second of the center piece And the first opening of the facet is substantially the same height. The method of claim 33, wherein And the opening of the first facet of the center piece is substantially the same height as the first opening of the second facet of the center piece. The method of claim 33, wherein And the center piece, the first side piece and the second side piece, when joined together, form a substantially cylindrical inner chamber region. The method of claim 33, wherein And the central piece comprises a bottom having a domed portion. The method of claim 36, Wherein the domed portion is coupled to a vacuum robot. The method of claim 36, The domed portion includes at least one support fin to reduce movement of the domed portion in the vertical direction. The method of claim 36, And the bottom of the center piece comprises a flat portion. The method of claim 39, Wherein said flat portion has a first thickness and said domed portion has a second thickness less than said first thickness. An electronic device manufacturing chamber support comprising one or more sliding mechanisms; And An electronic device manufacturing chamber support coupled to said at least one sliding mechanism, Wherein the one or more sliding mechanisms receive the electronic device manufacturing chamber expansion and prevent the electronic device manufacturing chamber from deviating from a location on the electronic device manufacturing chamber support. The method of claim 41, wherein Wherein the one or more sliding mechanisms contract to accommodate expansion of the electronic device manufacturing chamber. First piece; And At least one second piece coupled to the first piece Including, thereby forming a multi-piece electronic device manufacturing chamber, The size of each of the pieces follows at least one of ground or air transport regulations, Wherein the overall size of the electronic device manufacturing chamber does not follow at least one of ground or air transport regulations. The method of claim 43, An O-ring between the first piece and the second piece; And Means for coupling the first piece to the at least one second piece The multi-piece electronic device manufacturing chamber further comprising. The method of claim 43, And the second piece is horizontally coupled to the first piece. The method of claim 43, And the second piece is coupled perpendicularly to the first piece. One or more support members; And One or more sliding mechanisms coupled to the electronics manufacturing chamber and receiving expansion of the electronics manufacturing chamber so that the electronics manufacturing chamber does not leave its position on the base frame. The base frame comprising a Apparatus for supporting an electronic device manufacturing chamber comprising a. The method of claim 47, And the at least one sliding mechanism is further configured to retract in response to the electronic device manufacturing chamber expansion. A central piece comprising a bottom having a first side, a second side and a domed portion; A first side piece coupled with the first side of the center piece; And A second side piece coupled with the second side of the center piece Multi-piece chamber comprising a. The method of claim 49, Wherein the domed portion contains a vacuum robot. The method of claim 49, The domed portion includes at least one support fin to reduce movement of the domed portion in the vertical direction. The method of claim 51, The domed portion comprises a plurality of support fins, each support pin reducing the movement of the domed portion in the vertical direction. The method of claim 49, And the bottom of the center piece comprises a flat portion. The method of claim 53, Wherein said flat portion has a first thickness and said domed portion has a second thickness less than said first thickness. The method of claim 54, Wherein the first thickness is about 0.75 to 1 inch or less and the second thickness is about 0.375 inch or less. A center piece comprising a first side, a second side, and a bottom having a domed portion and a flat portion, wherein the flat portion has a first thickness and the domed portion has a second thickness less than the first thickness being-; A first side piece coupled with the first side of the center piece; And A second side piece coupled with the second side of the center piece Multi-piece chamber comprising a. The method of claim 56, wherein Wherein the first thickness is about 0.75 to 1 inch or less and the second thickness is about 0.375 inch or less. First side; Second side; A first facet including at least one opening and sized to allow a substrate to pass through the opening; And A second facet comprising at least three openings, each opening sized to allow a substrate to pass through the opening A central piece comprising a; A first side piece coupled to the first side of the center piece; And A second side piece coupled to the second side of the center piece Multi-piece chamber comprising a. A central piece comprising a first side and a second side; A first side piece coupled to the first side of the center piece; And A second side piece coupled to the second side of the center piece, wherein the first side of the center piece allows a substrate to be rotatable within the multi piece chamber and the substrate is a first side of the multi piece chamber from the multi piece chamber. Including at least one first notch allowing transfer to a chamber coupled to the piece; Multi-piece chamber comprising a. The method of claim 59, The second side of the center piece allows at least one first to enable the substrate to be rotatable within the multi piece chamber and to transfer the substrate from the multi piece chamber to a chamber coupled to the second side piece of the multi piece chamber. Multi piece chamber comprising a notch. A central piece comprising a first side and a second side; A first side piece coupled to the first side of the center piece, the first side piece including at least one fin structure to reduce movement of the sidewall of the first side piece; And A second side piece coupled to the second side of the center piece Multi-piece chamber comprising a. 62. The method of claim 61, The second side piece includes at least one fin structure to reduce movement of the sidewalls of the second side piece. A central piece comprising a first side and a second side; A first side piece coupled to the first side of the central piece, the first side piece including at least one support to reduce movement of the sidewall of the first side piece; And A second side piece coupled to a second side of the central piece, the second side piece including at least one support to reduce movement of the sidewall of the second side piece Including, And the center piece, the first side piece and the second side piece, when joined together, form a substantially cylindrical inner chamber region. A central piece comprising a first side and a second side; A first side piece coupled to the first side of the center piece; A second side piece coupled to the second side of the center piece; And Cover at least the center piece Including, The cover includes a flat portion and a plurality of support members to reduce movement of the flat portion in the vertical direction. 65. The method of claim 64, The cover includes at least one hatch to allow access to an interior region of the multi piece chamber without having to remove the cover. A central piece comprising a first side and a second side; A first side piece coupled to the first side of the center piece; A second side piece coupled to the second side of the center piece; And Cover at least the center piece A multi piece chamber comprising: The cover has at least one hatch to allow access to the interior area of the multi piece chamber without having to remove the cover. Multi-piece chamber comprising a. A first side piece of the multi piece chamber; A second side piece of the multi piece chamber, wherein the first and second side pieces are joined to a central piece to form the multi piece chamber; A first base frame coupled to the first side piece; And A second base frame coupled to the second side piece Unit comprising: the size of the unit complies with at least one of ground or air transport regulations; Device comprising a.

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