Abstract: An apparatus and related process are provided for vapor deposition of a sublimated source material as a thin film on a photovoltaic (PV) module substrate. A receptacle is disposed within a vacuum head chamber and is configured for receipt of a source material. A heated distribution manifold is disposed below the receptacle and includes a plurality of passages defined therethrough. The receptacle is indirectly heated by the distribution manifold to a degree sufficient to sublimate source material within the receptacle. A molybdenum distribution plate is disposed below the distribution manifold and at a defined distance above a horizontal plane of a substrate conveyed through the apparatus. The molybdenum distribution plate includes a pattern of holes therethrough that further distribute the sublimated source material passing through the distribution manifold onto the upper surface of the underlying substrate. The molybdenum distribution plate includes greater than about 75% by weight molybdenum.

Abstract: A conveyor assembly for use in a vapor deposition apparatus wherein a sublimed source material is deposited as a thin film on a photovoltaic (PV) module substrate. The assembly includes a conveyor movable in an endless loop path that includes an upper leg that moves in a conveyance direction to carry a substrate through a deposition area of the vapor deposition apparatus. A heat source is disposed relative to the endless loop path so as to heat the conveyor at a location generally after the point where substrates leave the conveyor. The heat source heats the conveyor to a temperature effective for sublimating source material from the conveyor. A cold trap is disposed relative to the endless loop path downstream of the heat source in a direction of movement of the conveyor and is maintained at a temperature effective for causing sublimated source material generated from heating the conveyor to plate out onto a collection member configured with the cold trap.

Abstract: An apparatus and related process are provided for vapor deposition of a sublimated source material as a thin film on a photovoltaic (PV) module substrate. A receptacle is disposed within a vacuum head chamber and is configured for receipt of a source material. A heated distribution manifold is disposed below the receptacle and includes a plurality of passages defined therethrough. The receptacle is indirectly heated by the distribution manifold to a degree sufficient to sublimate source material within the receptacle. A molybdenum distribution plate is disposed below the distribution manifold and at a defined distance above a horizontal plane of a substrate conveyed through the apparatus. The molybdenum distribution plate includes a pattern of holes therethrough that further distribute the sublimated source material passing through the distribution manifold onto the upper surface of the underlying substrate. The molybdenum distribution plate includes greater than about 75% by weight molybdenum.

Abstract: Apparatus and methods for testing the thermal endurance of a glass substrate of a photovoltaic module are provided. The apparatus generally includes, in one embodiment, a testing chamber defining an interior space having an interior atmosphere. A refrigeration unit is operably positioned with the testing chamber to control the interior atmosphere's temperature. A mounting system is positioned within the interior space of the testing chamber and configured to hold the photovoltaic module while exposing the glass substrate of the photovoltaic module. An edge cooling system is positioned in relation to the mounting system such that the photovoltaic module held by the mounting system has a first side edge in contact with the edge cooling system. A light system is also positioned within the interior space of the testing chamber to illuminate the glass substrate of the photovoltaic module.

Abstract: A module for a deposition system includes a drive unit mounted on an exterior wall of the module. The drive unit has a drive shaft that extends into the module and engages a conveyor operably disposed within the module for driving the conveyor in a conveying path. A releasable drive coupling is configured between the drive unit and a drive member of the conveyor. The drive coupling has a first end that releasably engages with the drive shaft and a second end that releasably engages the conveyor drive member. The drive coupling includes a torque member, and may also include at least one thermal shield spaced concentrically around the torque member and extending axially between the first and second ends.

Abstract: An apparatus and process for vapor deposition of a sublimated source material as a thin film on a photovoltaic module substrate are provided. The apparatus includes at least one receptacle disposed in a deposition head. Each receptacle is configured for receipt of a granular source material. A heating system is configured to heat the receptacle(s) to sublimate the source material. A substantially vertical distribution plate is disposed between the receptacle(s) and a substrate conveyed through the apparatus. The distribution plate is positioned at a defined distance from a vertical conveyance plane of a deposition surface of the substrate. The distribution plate comprises a pattern of passages therethrough that distribute the sublimated source material for deposition onto the deposition surface of the substrate.

Abstract: An apparatus and associated method of operation is provided for vapor deposition of a sublimated source material, such as CdTe, as a thin film on discrete photovoltaic (PV) module substrates that are conveyed in a continuous, non-stop manner through the apparatus. The apparatus includes a deposition head configured for receipt and sublimation of the source material. The deposition head has a distribution plate at a defined distance above a horizontal conveyance plane of an upper surface of the substrates conveyed through a deposition area within the apparatus. The sublimated source material moves through the distribution plate and deposits onto the upper surface of the substrates as they are conveyed through the deposition area. The substrates move into and out of the deposition area through entry and exit slots that are defined by transversely extending entrance and exit seals.

Abstract: A method for processing substrates in the formation of photovoltaic (PV) modules, the substrates having a plurality of thin film layers deposited thereon. The method includes determining the geometric center of the substrate and performing subsequent processing steps for defining individual cells on the substrate using the geometric center of the substrate as a starting reference point for such processing steps.

Abstract: Enhanced user selection interface structures comprise one or more buttons that are linked to selectable characteristics, and a display linked to the buttons, for display of an item that corresponds to the selected characteristics. The interface is typically linked to a database comprising stored images and other information that corresponds to the selectable characteristics, wherein an image that corresponds to an item that meets a selected characteristic is retrieved and displayed. Corresponding information other than the image may also be retrieved and displayed. In some embodiments, the stored images comprise a single image that matches all the selected characteristics. In alternate embodiments, the displayed image comprises a composite image that corresponds to different selected characteristics. In some embodiments, the user selection interface comprises any of a graphic user interface or a mechanical interface.

Abstract: A feed system and related process are configured to continuously feed measured doses of source material to a vapor deposition apparatus wherein the source material is sublimated and deposited as a thin film on a substrate. The system includes a bulk material hopper, and an upper dose cup disposed to receive source material from the hopper. A lower dose cup is disposed in a vacuum lock chamber to receive a measured dose of source material from the upper dose cup. A transfer mechanism is disposed below the vacuum lock chamber to receive the measured dose of source material from the lower dose cup and to transfer the source material to a downstream deposition head while isolating the deposition conditions and sublimated source material within the deposition head.

Abstract: A process and associated system for vapor deposition of a thin film layer on a photovoltaic (PV) module substrate is includes establishing a vacuum chamber and introducing the substrates individually into the vacuum chamber. The substrates are pre-heated as they are conveyed through the vacuum chamber, and are then conveyed in serial arrangement through a vapor deposition apparatus in the vacuum chamber wherein a thin film of a sublimed source material is deposited onto an upper surface of the substrates. The substrates are conveyed through the vapor deposition apparatus at a controlled constant linear speed such that leading and trailing sections of the substrate in a conveyance direction are exposed to the same vapor deposition conditions within the vapor deposition apparatus. The vapor deposition apparatus may be supplied with source material in a manner so as not to interrupt the vapor deposition process or non-stop conveyance of the substrates through the vapor deposition apparatus.

Abstract: An apparatus and related process are provided for vapor deposition of a sublimated source material as a thin film on a photovoltaic (PV) module substrate. A receptacle is disposed within a vacuum head chamber and is configured for receipt of a source material. A heated distribution manifold is disposed below the receptacle and includes a plurality of passages defined therethrough. The receptacle is indirectly heated by the distribution manifold to a degree sufficient to sublimate source material within the receptacle. A distribution plate is disposed below the distribution manifold and at a defined distance above a horizontal plane of a substrate conveyed through the apparatus. The distribution plate includes a pattern of holes therethrough that further distribute the sublimated source material passing through the distribution manifold onto the upper surface of the underlying substrate.

Abstract: A conveyor assembly for use in a vapor deposition apparatus includes a housing defining an enclosed interior volume. A conveyor is driven in an endless loop path within the housing. The housing has a top member that defines an open deposition area in an upper conveyance leg of the conveyor. The conveyor includes a plurality of interconnected slats, with each slat having a respective flat, planar outer surface and transverse edge profiles such that, in the upper conveyance leg of the conveyor, the outer surfaces of the slats lie in a common horizontal plane and define an uninterrupted flat support surface for a substrate conveyed through the vapor deposition apparatus.

Abstract: A system and associated process for vapor deposition of a thin film layer on a photovoltaic (PV) module substrate is includes establishing a vacuum chamber and introducing the substrates individually into the vacuum chamber. A conveyor system is operably disposed within the vacuum chamber and is configured for conveying the substrates in a serial arrangement through a vapor deposition apparatus within the vacuum chamber at a controlled constant linear speed. A post-heat section is disposed within the vacuum chamber immediately downstream of the vapor deposition apparatus in the conveyance direction of the substrates. The post-heat section is configured to maintain the substrates conveyed from the vapor deposition apparatus in a desired heated temperature profile until the entire substrate has exited the vapor deposition apparatus.

Abstract: An apparatus and related process are provided for vapor deposition of a sublimated source material as a thin film on a photovoltaic (PV) module substrate. A receptacle is disposed within a vacuum head chamber and is configured for receipt of a source material. A heated distribution manifold is disposed below the receptacle and includes a plurality of passages defined therethrough. The receptacle is indirectly heated by the distribution manifold to a degree sufficient to sublimate source material within the receptacle. A molybdenum distribution plate is disposed below the distribution manifold and at a defined distance above a horizontal plane of a substrate conveyed through the apparatus. The molybdenum distribution plate includes a pattern of holes therethrough that further distribute the sublimated source material passing through the distribution manifold onto the upper surface of the underlying substrate. The molybdenum distribution plate includes greater than about 75% by weight molybdenum.

Abstract: A conveyor assembly for use in a vapor deposition apparatus wherein a sublimed source material is deposited as a thin film on a photovoltaic (PV) module substrate. The assembly includes a conveyor movable in an endless loop path that includes an upper leg that moves in a conveyance direction to carry a substrate through a deposition area of the vapor deposition apparatus. A heat source is disposed relative to the endless loop path so as to heat the conveyor at a location generally after the point where substrates leave the conveyor. The heat source heats the conveyor to a temperature effective for sublimating source material from the conveyor. A cold trap is disposed relative to the endless loop path downstream of the heat source in a direction of movement of the conveyor and is maintained at a temperature effective for causing sublimated source material generated from heating the conveyor to plate out onto a collection member configured with the cold trap.

Abstract: An Internet wire-mesh merchandising system comprises a webserver for generating a web presence. Potential customers are allowed to log-on to a website operated by a retailer, distributor, and manufacturer. An HTML product page includes navigation buttons that link to other HTML product pages. Each page further includes JPG or GIF type pictures that allow the shopper to see a particular product corresponding to a presently displayed HTML product page. A group of alternate-view buttons link to other pictures of the same product that show variations or different perspectives. A set of four navigation buttons permit the shopper to hyperlink to HTML product pages. Once the link is taken, a graphic is presented. The list of hyperlinks includes only those HTML product pages that represent available combinations. A “price” and an “order” hypertext allow the shopper to see the product price for the selected item and to order it electronically.

Abstract: A drawer refrigerator has a partitioned cabinet with one or more pull-out drawers. The pull-out drawer(s) can have an adjustable divider fence for dividing the storage space of the drawer. The divider fence can have two dividers each defined by two spaced apart elongated rods that are coupled together at a hub and have end pieces with flat surfaces that abut inside surfaces of the drawer walls. A hand operated screw knob mounted to the hub can be used to lock the position of the divider fence.

Abstract: A user selection interface system comprises one or more circular selectors linked to selectable characteristics, and a display linked to the selectors, for display of an image which corresponds to the selected characteristics. The interface is typically linked to a database comprising stored image and other information which corresponds to the selectable characteristics, whereby an image that corresponds to an item which meets a selected characteristic is retrieved and displayed. Information other than the image which corresponds to the selectable characteristics may also be retrieved and displayed. In some embodiments, the stored images comprise a single image, which matches all the selected characteristics. In alternate embodiments, the displayed image comprises a composite image that is based upon stored images which correspond to different selected characteristics. In some embodiments, the user selection interface comprises a graphic user interface.

Abstract: A spring loaded camming device and a trigger mechanism therefor. The trigger mechanism may include an axle, an inner and outer cam, a flexible stem, a trigger handle, and a trigger wire passing through the trigger wire and coupling in an efficient and effective manner, the inner and outer cams to each other and to the trigger handle. A bias member may be associated with the trigger wire, particularly in asymmetric type camming devices. Various embodiments are disclosed.