Abstract: A system for delivering and applying a flowable mixture to an article (311-313) is disclosed. The system includes a mixture delivery system (200) and a skinning system (300). The mixture delivery system (200) includes a mixer (220) configured to mix a dry material and a fluid to produce the flowable mixture, and a pump (235) configured to pump the flowable mixture to a delivery line. The skinning system (300) receives the flowable mixture from the mixture delivery system (200) through the delivery line. The skinning system (300) includes a skinning pipe (310) configured to apply the flowable mixture to the article (311-313) and a manifold (305) that supports the skinning pipe (310). The skinning system (300) also includes an article feeding mechanism (315) configured to push the article (311-313) into the skinning pipe (310). The skinning system (300) includes a transfer system (320) configured to hold the article (311-313) and move the article (311-313) out of the skinning pipe (310).

Abstract: A glass body support assembly that supports a glass container body in an upright position includes a collet body and clamping fingers that clamp onto a necked-down portion of the glass container body. The collet body has a gas purge passageway extending therethrough to deliver pressurized gas to an interior of the glass container body.

Abstract: A process for thermally strengthening a glass article comprising first conveying a glass article, having a temperature above a transition point of the glass of the article, into position between two fluid bearing surfaces then moving the fluid bearing surfaces toward the glass article and cooling the glass article, with at least 20% of said cooling taking place by conduction from the glass article to the fluid bearing surfaces. Apparatuses for performing the process and products resulting are also disclosed.

Abstract: Methods, computer readable storage media, and systems are provided for generating machine-readable biometric data from a medical device, which may include: obtaining an image of the medical device including a display of the medical device; retrieving a reference image of a reference display corresponding to the medical device, the reference image defining a reference data field within the reference display; comparing the image to the reference image to identify a data field within the display corresponding to the reference data field within the reference display; identifying one or more alpha-numeric symbols within the data field; and converting the alpha-numeric symbols into the machine-readable biometric data. The machine-readable biometric data may be used to create a data record for a user of the medical device, and can be communicated to an Independent Diagnostic Testing Facility (IDTF) database or server.

Abstract: According to one embodiment, an apparatus for holding may include a plurality of ware keepers for receiving glassware. Each ware keeper may include a retention body comprising a wire coil circumscribing a glassware receiving volume. A lower-most winding of the wire coil forms a ware stop in the retention body. The retention body may include a spacer coil extending from the retention body below the ware stop. A base frame may include a plurality of apertures extending through the base frame. Each of the plurality of ware keepers may be positioned in a corresponding aperture in the base frame such that the retention body of each ware keeper is above a top surface of the base frame and the spacer coil of each ware keeper is below a bottom surface of the base frame.

Abstract: A coating carrier for use with a glass coating apparatus includes a coating base comprising a plurality of spindle connector receiving features. Each spindle connector receiving feature includes a cavity that is sized to movably receive a spindle connector of a glass body support assembly that is configured to support a glass container body.

Abstract: A system for delivering and applying a flowable mixture to an article (311-313) is disclosed. The system includes a mixture delivery system (200) and a skinning system (300). The mixture delivery system (200) includes a mixer (220) configured to mix a dry material and a fluid to produce the flowable mixture, and a pump (235) configured to pump the flowable mixture to a delivery line. The skinning system (300) receives the flowable mixture from the mixture delivery system (200) through the delivery line. The skinning system (300) includes a skinning pipe (310) configured to apply the flowable mixture to the article (311-313) and a manifold (305) that supports the skinning pipe (310). The skinning system (300) also includes an article feeding mechanism (315) configured to push the article (311-313) into the skinning pipe (310). The skinning system (300) includes a transfer system (320) configured to hold the article (311-313) and move the article (311-313) out of the skinning pipe (310).

Abstract: A mold assembly includes a mold having a mold cavity defined by a mold surface having a three-dimensional shape and at least one opening for communication of fluid or vacuum to the mold cavity. A plenum base is mounted to the mold such that a chamber is defined between the plenum base and the mold, where the chamber is in communication with the at least one opening in the mold. A cooling plate is arranged in the chamber. A fluid passage is defined between the concentrically arranged outer tube and inner tube coupled to the plenum base. One fluid conduit extends through the inner tube and a first opening in the plenum base to the chamber. Another fluid conduit extends from the fluid passage through a side port in the outer tube and a second opening in the plenum base to the cooling plate.

Abstract: Methods, computer readable storage media, and systems are provided for generating machine-readable biometric data from a medical device, which may include: obtaining an image of the medical device including a display of the medical device; retrieving a reference image of a reference display corresponding to the medical device, the reference image defining a reference data field within the reference display; comparing the image to the reference image to identify a data field within the display corresponding to the reference data field within the reference display; identifying one or more alpha-numeric symbols within the data field; and converting the alpha-numeric symbols into the machine-readable biometric data. The machine-readable biometric data may be used to create a data record for a user of the medical device, and can be communicated to an Independent Diagnostic Testing Facility (IDTF) database or server.

Abstract: A method of determining extrinsic calibration parameters for at least one sensor (102, 104, 106) mounted on transportable apparatus (100). The method includes receiving (202) data representing pose history of the transportable apparatus and receiving (202) sensor data from at least one sensor mounted on transportable apparatus. The method generates (204) at least one point cloud data using the sensor data received from the at least one sensor, each point in a said point cloud having a point covariance derived from the pose history data. The method then maximizes (206) a value of a quality function for the at least one point cloud, and uses (208) the maximized quality function to determine extrinsic calibration parameters for the at least one sensor.

Abstract: According to one embodiment, an apparatus for holding may include a plurality of ware keepers for receiving glassware. Each ware keeper may include a retention body comprising a wire coil circumscribing a glassware receiving volume. A lower-most winding of the wire coil forms a ware stop in the retention body. The retention body may include a spacer coil extending from the retention body below the ware stop. A base frame may include a plurality of apertures extending through the base frame. Each of the plurality of ware keepers may be positioned in a corresponding aperture in the base frame such that the retention body of each ware keeper is above a top surface of the base frame and the spacer coil of each ware keeper is below a bottom surface of the base frame.

Abstract: A mold assembly includes a mold having a mold cavity defined by a mold surface having a three-dimensional shape and at least one opening for communication of fluid or vacuum to the mold cavity. A plenum base is mounted to the mold such that a chamber is defined between the plenum base and the mold, where the chamber is in communication with the at least one opening in the mold. A cooling plate is arranged in the chamber. A fluid passage is defined between the concentrically arranged outer tube and inner tube coupled to the plenum base. One fluid conduit extends through the inner tube and a first opening in the plenum base to the chamber. Another fluid conduit extends from the fluid passage through a side port in the outer tube and a second opening in the plenum base to the cooling plate.

Abstract: A glass molding system and a method of making glass articles using the glass molding system are disclosed. The glass molding system includes an indexing table, a plurality of enclosures arranged along the indexing table, and a plurality of stations defined on the indexing table such that each of the stations is selectively indexable with any one of the enclosures. At least one radiant heater is arranged in at least one of the enclosures. A radiation reflector surface and a radiation emitter body are arranged in the at least one of the enclosures. The radiation emitter body is between the at least one radiant heater and the radiation reflector surface and has a first surface in opposing relation to the at least one radiant heater and a second surface in opposing relation to the radiation reflector surface.

Abstract: A method of determining extrinsic calibration parameters for at least one sensor (102, 104, 106) mounted on transportable apparatus (100). The method includes receiving (202) data representing pose history of the transportable apparatus and receiving (202) sensor data from at least one sensor mounted on transportable apparatus. The method generates (204) at least one point cloud data using the sensor data received from the at least one sensor, each point in a said point cloud having a point covariance derived from the pose history data. The method then maximises (206) a value of a quality function for the at least one point cloud, and uses (208) the maximised quality function to determine extrinsic calibration parameters for the at least one sensor.

Abstract: A glass molding system and a method of making glass articles using the glass molding system are disclosed. The glass molding system includes an indexing table, a plurality of enclosures arranged along the indexing table, and a plurality of stations defined on the indexing table such that each of the stations is selectively indexable with any one of the enclosures. At least one radiant heater is arranged in at least one of the enclosures. A radiation reflector surface and a radiation emitter body are arranged in the at least one of the enclosures. The radiation emitter body is between the at least one radiant heater and the radiation reflector surface and has a first surface in opposing relation to the at least one radiant heater and a second surface in opposing relation to the radiation reflector surface.

Abstract: A glass molding system and a method of making glass articles using the glass molding system are disclosed. The glass molding system includes an indexing table, a plurality of enclosures arranged along the indexing table, and a plurality of stations defined on the indexing table such that each of the stations is selectively indexable with any one of the enclosures. At least one radiant heater is arranged in at least one of the enclosures. A radiation reflector surface and a radiation emitter body are arranged in the at least one of the enclosures. The radiation emitter body is between the at least one radiant heater and the radiation reflector surface and has a first surface in opposing relation to the at least one radiant heater and a second surface in opposing relation to the radiation reflector surface.

Abstract: A glass molding system and a method of making glass articles using the glass molding system are disclosed. The glass molding system includes an indexing table, a plurality of enclosures arranged along the indexing table, and a plurality of stations defined on the indexing table such that each of the stations is selectively indexable with any one of the enclosures. At least one radiant heater is arranged in at least one of the enclosures. A radiation reflector surface and a radiation emitter body are arranged in the at least one of the enclosures. The radiation emitter body is between the at least one radiant heater and the radiation reflector surface and has a first surface in opposing relation to the at least one radiant heater and a second surface in opposing relation to the radiation reflector surface.

Abstract: A glass molding system and a method of making glass articles using the glass molding system are disclosed. The glass molding system includes an indexing table, a plurality of enclosures arranged along the indexing table, and a plurality of stations defined on the indexing table such that each of the stations is selectively indexable with any one of the enclosures. At least one radiant heater is arranged in at least one of the enclosures. A radiation reflector surface and a radiation emitter body are arranged in the at least one of the enclosures. The radiation emitter body is between the at least one radiant heater and the radiation reflector surface and has a first surface in opposing relation to the at least one radiant heater and a second surface in opposing relation to the radiation reflector surface.

Abstract: Provided is an anode for use in electrochemical cells, wherein the anode active layer has a first layer comprising lithium metal and a multi-layer structure comprising single ion conducting layers and polymer layers in contact with the first layer comprising lithium metal or in contact with an intermediate protective layer, such as a temporary protective metal layer, on the surface of the lithium-containing first layer. Another aspect of the invention provides an anode active layer formed by the in-situ deposition of lithium vapor and a reactive gas. The anodes of the current invention are particularly useful in electrochemical cells comprising sulfur-containing cathode active materials, such as elemental sulfur.

Abstract: Provided is an anode for use in electrochemical cells, wherein the anode active layer has a first layer comprising lithium metal and a multi-layer structure comprising single ion conducting layers and polymer layers in contact with the first layer comprising lithium metal or in contact with an intermediate protective layer, such as a temporary protective metal layer, on the surface of the lithium-containing first layer. Another aspect of the invention provides an anode active layer formed by the in-situ deposition of lithium vapor and a reactive gas. The anodes of the current invention are particularly useful in electrochemical cells comprising sulfur-containing cathode active materials, such as elemental sulfur.