Abstract:
A chamber with a fluid distribution network for uniform fluid flow within the chamber is provided. The chamber includes a first chamber wall that has a first surface and an opposing interior surface. The first surface is formed with a first set of channels, and the interior surface is exposed to the interior of the chamber and includes a plurality of interior ports that are connected to a plurality of the first set of channels. The chamber also includes a second chamber wall that has a second surface and an opposing exterior surface. The second surface has a second set of channels that partially intersect the first set of channels when the first surface is mated with the second surface. The exterior surface also includes at least one exterior port that provides access to the second set of channels.

Description:
BACKGROUND 
     In many manufacturing processes for semiconductor and magnetic disk manufacturing, it is necessary to treat a work piece in a liquid environment and then dry the work piece. As is well known, particulates or contaminates that attach during the drying process may eventually cause defects in the work piece. Additionally, an inefficient drying process may result in extended processing times or even leave defects on a surface of the work piece, as well as promote oxidation. Thus, it is extremely important that when a substrate is dried, there are no impurities left on its surface. In order to promote efficient drying and reduce the likelihood of forming impurities, the embodiments described below expose the work pieces to evenly distributed heated gas after the work pieces are removed from the liquid environment. 
     SUMMARY 
     In one embodiment, a chamber with a fluid distribution network for uniform fluid flow within the chamber is provided. The chamber includes a first chamber wall that has a first surface and an opposing interior surface. The first surface is formed with a first set of channels and the interior surface is exposed to the interior of the chamber. The chamber also includes a plurality of interior ports that are connected to a plurality of the first set of channels. The chamber also includes a second chamber wall that has a second surface and an opposing exterior surface. The second surface has a second set of channels that partially intersecting the first set of channels when the first surface is mated with the second surface. The exterior surface also includes at least one exterior port providing access to the second set of channels. 
     In another embodiment a fluid distribution chamber is provided. The fluid distribution chamber includes a base that has sidewalls extending therefrom. Wherein one of the sidewalls includes a first member and a second member affixed to each other. The first member has an inner surface that mates with an outer surface of the second member. The inner surface of the first member also has a plurality of cavities defined in a first pattern of spaced apart rows. While the outer surface has a plurality of cavities defined in a second pattern of spaced apart columns. Wherein a cavity of the first pattern partially intersects with multiple cavities in the second pattern. 
     In still another embodiment, a method for distributing a fluid is disclosed. The method includes operations that provide a chamber that has a first and second walls affixed to each other that form a uniform fluid distribution network. Another operation initiates fluid flow through a port that is connected to the uniform fluid distribution network within the affixed walls. In another operation fluid flow is distributed within the affixed walls. The fluid flow being uniformly distributed between the walls through a first set of channels formed as part of the first wall that partially intersect an opposing second set of channels formed as part of the second wall. 
     Other aspects and advantages of the invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, illustrating by way of example the principles of the invention. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention, together with further advantages thereof, may best be understood by reference to the following description taken in conjunction with the accompanying drawings. 
         FIG. 1  is a simplified schematic diagram illustrating an overview of a substrate cleaning system using a fluid distribution network in accordance with one embodiment of the invention. 
         FIG. 2  is an exemplary illustration of the drying chamber in accordance with one embodiment of the present invention. 
         FIG. 3  is an exemplary illustration of an exploded view of a portion of drying chamber in accordance with one embodiment of the present invention. 
         FIGS. 4A and 4B  are exemplary views of the alignment of the vertical and horizontal channels of the vertical distribution plate and the horizontal distribution plate in accordance with one embodiment of the present invention. 
         FIGS. 5A and 5B  are schematics showing the vertical distribution plate and the horizontal distribution plate in accordance with one embodiment of the present invention. 
         FIGS. 6A-6E  are exemplary schematics illustrating various flow patterns that could be established within a chamber in accordance with embodiments of the present invention. 
         FIG. 7  is a flow chart illustrating exemplary operations for a method to evenly distribute a fluid within a chamber in accordance with one embodiment of the present invention. 
     
    
    
     DETAILED DESCRIPTION 
     An invention is disclosed for evenly dispensing and/or removing a fluid within a chamber. As described below, in one embodiment the fluid can be a gas to effectuate drying of substrate materials. However, the claims should not be construed to limit the type of fluid capable of being dispensed and/or removed within the chamber to drying gases. One skilled in the art should recognize that a chamber including the claimed subject matter could be modified to accommodate liquids or gases. Other embodiments include chambers that are able to switch between configurations for distributing gases to a configuration for distributing liquids. Additionally, while the description below describes a chamber for drying substrate materials, in other embodiments, the chamber may be scaled to include fluid circulation for larger structures such as clean rooms or entire buildings. 
     In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It will be apparent, however, to one skilled in the art that the present invention may be practiced without some or all of these specific details. In other instances, well known process steps have not been described in detail in order not to unnecessarily obscure the present invention. 
       FIG. 1  is a simplified schematic diagram illustrating an overview of a substrate cleaning system  100  using a fluid distribution network in accordance with one embodiment of the invention. The substrate cleaning system  100  can include a drying chamber  102 , a cleaning tank  104 , and a transport assembly  108 . After controlled exposure within the cleaning tank  104 , substrate materials are moved via the transport assembly  108  to the drying chamber  102 . For further information regarding the transport assembly  108 , please see U.S. patent application Ser. No. 11/531,905, filed on Sep. 14, 2006 titled A PPARATUS AND  M ETHOD FOR  D RYING A  S UBSTRATE , which is herein incorporated by reference. 
     Heated drying gases are distributed throughout the length of the drying chamber  102  in an effort to provide uniform process exposure to the substrate materials. In order to achieve process uniformity, it is desirable to have uniform flow of the drying gases across the entire drying chamber to minimize temperature fluctuations within the drying chamber. 
       FIG. 2  is an exemplary illustration of the drying chamber  102  in accordance with one embodiment of the present invention. The interior of the drying chamber  102  is formed by horizontal distribution plates  200   a/b  and end walls  204   a/b . As will be discussed below, the horizontal distribution plates  200   a/b  have horizontal channels or grooves formed on a surface to assist in the distribution of fluid throughout the drying chamber  102 . Mated to the horizontal distribution plates  200   a/b  are vertical distribution plates  202   a/b  that will also be discussed in more detail below. As shown in  FIG. 2 , the horizontal distribution plate  200   b  can include ports  208  that are open to the interior of the drying chamber  102 . Note that ports  208  are also found on the horizontal distribution plate  200   a  but are not visible in  FIG. 2 . 
     In one embodiment of the drying chamber  102 , heated drying gases are uniformly dispensed from ports  208  to minimize temperature fluctuations within the drying chamber  102 . In other embodiments, gases at varying temperatures, mixtures of liquids at various temperatures, and mixtures of liquids and gases can be dispensed or removed from ports  208 . Exterior walls  214  can be affixed to the vertical distribution plates  202   a/b  to provide insulation for embodiments where temperature control of the chamber is desired. The exterior walls  214  can also be used to increase the robustness of the chamber. The location, shape, and number of ports  208  shown in  FIG. 2  are exemplary and should not be construed to limit the scope of the claims. Furthermore, the location, size, and configuration of the ports  208  can be modified as different uses of the chamber may require different fluid flow patterns and different fluid throughput in and out of the chamber. 
     Vertical distribution plates  202   a/b  are laminated or secured to their respective horizontal distribution plates  200   a/b . The vertical distribution plates  202   a/b  include vertical channels or grooves formed on a surface that is mated with the respective horizontal grooves of horizontal distribution plates  200   a/b  to assist in the distribution of fluid throughout the drying chamber  102 . The vertical distribution plates  202   a/b  also include ports  206  that provide access to the vertical channels. In some embodiments, fluid supplies can be attached to ports  206  in order to distribute fluids to ports  208 . In other embodiments, a vacuum can be attached to ports  206  in order to remove fluids through ports  208 . The combination of fluid supply and vacuum can be used to circulate fluids within the drying chamber  102 . 
     As previously discussed, the chamber  102  can also be used to circulate liquids and combinations of liquid supply and return could be used to circulate liquids within a chamber as well. For example, cleaning tank  104  could use laminated walls to distribute and circulate cleaning liquids to facilitate the removal of contaminates from a work piece. The number of ports  206  can be configured based on each application and can vary depending on necessary throughput and the flow configuration within the chamber. In other embodiments where the chamber can be used for multiple processes, ports  206  can be opened and closed to modify the number of ports  206 . 
     Both the vertical distribution plates  202   a/b  and the horizontal distribution plates  200   a/b  can also include additional ports  212  to provide access to the interior of the drying chamber  102 . The ports  212  can be used to install sensors or other equipment such as, but not limited to, resonators, transducers, flow meters, hygrometers, and thermocouples to monitor various conditions within the drying chamber. The drying chamber  102  can also include exterior walls  214  that are secured to the vertical distribution plates  202   a/b.    
     Note that the description of the distribution plates as “horizontal” and “vertical” is intended to describe the embodiment shown in  FIG. 2 . One skilled in the art should recognize that the descriptors of “horizontal” and “vertical” should not interpreted to limit the claims because other embodiments of the distribution plates may have an unlimited variety of channel configurations capable of distributing fluid between the distribution plates. 
       FIG. 3  is an exemplary illustration of an exploded view of a portion of drying chamber  102  in accordance with one embodiment of the present invention. Vertical grooves can be seen on a surface of the vertical distribution plate  202   b . Similarly, horizontal grooves can be seen on a surface of horizontal distribution plate  200   a . Also visible on horizontal distribution plate  200   a  are ports  210  that in this embodiment are diagonally opposed to ports  208 . Depending on the type of flow desired within the chamber, the ports  208  and the ports  210  can be placed in a variety of positions. In other embodiments, additional ports or fewer ports can be used to distribute various fluids to the chamber. In the embodiment shown in  FIG. 3 , Ports  210  can distribute fluids to an area below the drying chamber  102 . Ports  210  can also be found on horizontal distribution plate  200   b  but are not visible in  FIG. 3 . 
     In one embodiment, ports  206  are used to supply and return fluids that are distributed via the vertical and horizontal channels to/from ports  210  and ports  208 . In other embodiments, a vacuum can be drawn through ports  206  thereby using ports  208  and ports  210  to evacuate fluids from the chamber. In other embodiments, various configurations within the vertical and horizontal distribution plates along with various configurations of fluid supply and vacuum through ports  206  can allow both fluid removal and fluid distribution through ports  208  and/or ports  210 . 
       FIGS. 4A and 4B  are exemplary views of the alignment of the vertical and horizontal channels of the vertical distribution plate  202   b  and the horizontal distribution plate  200   b  in accordance with one embodiment of the present invention. In this view, the horizontal distribution plate  200   b  has been made semi-translucent in order to see features of the vertical distribution plate  202   b . In this embodiment, ports  206   a - 206   d  provide access to the distribution network formed by intersections between the horizontal distribution plate  200   b  and the vertical distribution plate  202   b . As seen in  FIG. 4A , port  206   a  provides fluid distribution and/or return to the plurality of ports  208   a . Likewise, ports  206   b - 206   d  can provide fluid distribution and/or exhaust to the respective ports  208   b  and ports  210   c/d.    
       FIG. 4B  illustrates additional details of the right side of the horizontal and vertical distribution plates shown in  FIG. 4A . Fluid introduced through port  206   d  passes through a volumetric area created by the intersection between the channels of the horizontal distribution plate  200   b  and the vertical distribution plate  202   b . Intersecting areas  400   a/b  allow the fluid to split into two separate horizontal channels in the horizontal distribution plate  200   b . In one embodiment, a summation of the cross-sectional area of a row of channels will result in substantially equal numbers for every row within the horizontal distribution plate  200   b . Similarly, the sum of the cross-sectional areas of the vertical channels remains substantially equal for vertical distribution plate  202   b . Maintaining a same cross-sectional area between the rows of horizontal and vertical channels promotes uniform fluid flow to all of the ports  208  and  210 . 
     Looking at the distribution network associated with port  206   d , intersecting the two horizontal channels  401   a/b  are four vertical channels  402   a - 402   d  that transport the fluid to four horizontal channels  403   a - 403   d . In some embodiments, horizontal channels  401   a/b  can be viewed as a row of horizontal channels while vertical channels  402   a - 402   d  can be viewed as a row of vertical channels. Similarly, horizontal channels  403   a - 403   d  can also be viewed as a row of horizontal channels. Thus, the distribution network can be viewed as a collection of intersecting vertical and horizontal rows. In the embodiment illustrated in  FIG. 4B , the distribution network associated with port  206   d  can be viewed to have five rows of horizontal channels and five rows of vertical channels (including the ports  210   d ). This is slightly different than the distribution network associated with ports  208   b  that have five rows of horizontal channels and four rows of vertical channels. 
     As previously described, the sum of the cross-sectional areas for horizontal channels  401   a/b  is approximately equal to the sum of the cross-sectional area of horizontal channels  403   a - 403   d . The fluid that passes through port  206   d  continues to be split vertically and horizontally until the fluid is evenly distributed across a specified length of the drying chamber. In this example, the fluid introduced through port  206   d , eventually emerges from ports  210   d  and the sum of the cross-sectional area of ports  210  would be approximately equal to the sum of the cross-sectional area of horizontal channels  401   a  and  401   b.    
     In some embodiments, summing the cross-sectional areas of each of the ports  210   d  could result in the cross-sectional area of the port  206   d . In other embodiments, fluids can be removed through port  206   d  and the distribution network formed between the horizontal distribution plate  202   b  and the vertical distribution plate  200   b  would evenly remove fluid from across the specified length of the chamber. 
       FIGS. 5A and 5B  are schematics showing the vertical distribution plate  202   b  and the horizontal distribution plate  200   b  respectfully in accordance with one embodiment of the present invention. Separating the vertical distribution palate  202   b  and the horizontal distribution plate  200   b , the cascading nature between the vertical and horizontal channels is evident. The cascading nature of the channels can also enable conservation of energy in chambers where heated or cooled fluids are flowing in and out of the chamber. In embodiments where fluid is input to the chamber, the conservation of energy within the chamber is promoted by transferring some of the incoming fluid energy to the chamber walls. In embodiments where fluid is evacuated from the chamber using a vacuum, some of the outgoing fluid energy can be transferred to the chamber walls. 
     As illustrated in  FIGS. 5A and 5B , the ports  206   a - 206   d  are on an opposite plate than ports  210  and/or ports  208 . However, in other embodiments, where space constraints may be an issue, the horizontal and vertical channels can be configured so ports  206   a - 206   d  can be located on the same distribution plate as ports  210  and/or  208 . In either embodiment, space saving and a reduction of an overall footprint of the chamber can be realized by placing input/output hardware necessary for ports  206   a - 206   d  within the chamber footprint. 
       FIGS. 6A-6E  are exemplary schematics illustrating various flow patterns that could be established within a chamber in accordance with embodiments of the present invention. In each of the figures the smaller diagrams on the left and right illustrate a type of connection to the ports feeding the distribution network. The various configurations shown should not be construed as limiting as various flow possibilities and port positions can be used to create endless flow configurations and flow patterns. One skilled in the art should also recognize that either gases or liquids could be supplied, distributed and/or returned within the distribution network.  FIG. 6A  illustrates a flow pattern that could be established by applying a vacuum to ports located on the bottom of a chamber and introducing fluid through ports at the top of the chamber. In this embodiment cross-flow can be established from the top of one side of the chamber to the bottom of the opposing side. 
       FIG. 6B  illustrates a cross-flow pattern that could be established by applying a vacuum to one side of the chamber while supplying fluid to the opposite side of the chamber.  FIG. 6C  is another exemplary flow pattern that could be induced by applying various vacuum and fluid supplies to a chamber utilizing fluid distribution plates. In this embodiment, fluid can be supplied through the ports at the top of the chamber while a vacuum evacuates fluid from the bottom of the chamber. 
       FIG. 6D  illustrates as exemplary flow pattern that can be created by not using all of the available ports. In this embodiment, the bottom ports on one side can be used to supply a fluid while the upper ports on the opposite side draw a vacuum. The ability to engage or disengage input and output from the chamber can provide flexibility and allow a single chamber to perform multiple processing operations. Additionally, the fluid distribution plates can be scaled to accommodate various size chambers including, but not limited to rooms within structures or even entire structures. In larger embodiments, where fabrication of the distribution plates from a single piece of material could be difficult, it may be necessary to use modular construction techniques in order to simplify the manufacturing process. 
       FIG. 6E  illustrates an embodiment where an exemplary flow pattern is established to remove fluid from the interior of the chamber. Applying a vacuum to all or some of the lower ports can create such a flow pattern. In other embodiments, gravity can be used in place of a vacuum to draw fluid from the chamber. 
       FIG. 7  is a flow chart illustrating exemplary operations for a method to evenly distribute a fluid within a chamber in accordance with one embodiment of the present invention. Operation  700  provides a chamber with walls that form a fluid distribution network. In one embodiment, the fluid distribution network can be formed between horizontal distribution plates and vertical distribution plates. As previously discussed, the distribution plates can have channels or grooves that intersect or overlap when affixed together to form the distribution network. 
     Operation  702  initiates fluid flow within the distribution network. As previously discussed, the fluid flow can be initiated via a port connected to the distribution network. In some embodiments, fluid can be input to the distribution network, while in other embodiments, fluid can be removed from the distribution network. 
     Operation  704  distributes the fluid flow within the chamber formed by the distribution plates. In some embodiments, the cascading nature of the distribution network can promote the even distribution of fluid. In some embodiments, the distribution network promotes even distribution of fluid within the distribution network by reducing cross-sectional area of the individual channels while increasing the number of individual channels to maintain a constant cross-sectional area for fluid to flow. 
     Although the foregoing invention has been described in some detail for purposes of clarity of understanding, it will be apparent that certain changes and modifications may be practiced within the scope of the appended claims. Accordingly, the present embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein, but may be modified within the scope and equivalents of the appended claims.