Abstract: A fluid flow plate for an electrochemical fuel cell assembly comprises a first plurality of fluid flow channels extending across an area of the flow plate to define a flow field of the fluid flow plate. An array of first fluid transfer points is disposed along an edge of the flow field for communicating fluid into to or out of the fluid flow channels. A gallery has a first peripheral edge portion bounded by the array of first fluid transfer points and at least two second peripheral edge portions each bounded by an array of second fluid transfer points disposed along fluid access edges of the fluid flow plate. The at least two second peripheral edge portions are disposed at oblique angles to the first peripheral edge portion such that the total length of the array of second fluid transfer points is at least as long as, and preferably longer than, the length of the array of first fluid transfer points.

Abstract: A fluid flow plate for an electrochemical assembly has a plurality of first fluid flow channels extending across an active area of the flow plate to define a first fluid flow field of the fluid flow plate and a plurality of second fluid flow channels extending across the active area of the flow plate to define a second fluid flow field of the fluid flow plate. An array of first fluid transfer points is disposed along an edge of the first fluid flow field for communicating fluid into or out of the first fluid flow channels. An array of second fluid transfer points is disposed along an edge of the second fluid flow field for communicating fluid into or out of the second fluid flow channels. A first fluid gallery a first peripheral edge portion bounded by the array of first fluid transfer points and has a second peripheral edge portion forming a first fluid communication edge of the fluid flow plate.

Abstract: Methods and apparatus for a network element or server end station to determine an estimated physical location of a fault in a communications link utilized by two network elements. In an embodiment, the first and second network elements generate link failure indications including time values representing when the respective network element detected the fault. In other embodiments, the link failure indications include time values transmitted over the communications link between the first and second network elements. A time distance between these time values is calculated, which is used to calculate the estimated physical location of the fault. In some embodiments, the link failure indications include sequence numbers transmitted or about to be transmitted over the communications link between the network elements. Sequence distances are calculated between the sequence numbers, and are used to calculate the estimated physical location of the fault.

Abstract: Methods and apparatus for determining an estimated physical location of a fault in a pipeline or electrical transmission line using localization devices coupled thereto. In an embodiment, a first and second localization device each generate time values representing times when the respective localization device detected the fault. The estimated fault location is calculated, by one of the localization devices or a separate computing device, based upon the reported time values. In some embodiments, the calculation is further based upon characteristics of the pipeline or electrical transmission line, or based upon characteristics of matter transported through the pipeline. In some embodiments, the localization devices transmit time or sequence values to the other device, and the values received by the devices just before the detection of the fault may additionally be utilized to calculate the estimated physical location of the fault.

Abstract: A system provides multidimensional tuple Hilbert ordering within a linear storage structure to enable more consistent and efficient access to stored multidimensional tuples. The database system comprises a tuple storage module that receives multidimensional data elements, where each multidimensional data element is defined by a plurality of different object types, and where each object is associated with a different dimension within a multidimensional data space. The tuple storage module further forms a respective tuple for each of the multidimensional data elements by mapping each object to an associated reference and applies a Hilbert function to the references of each of the tuples to determine a respective Hilbert ordering for each of the tuples. The system further comprises a linear data storage structure that includes a B-tree for storing the Hilbert ordering.

Abstract: Methods and related radio base stations (RBS) for handling data traffic are disclosed. The RBS is connected to a remote node via a wireless channel and to a centralized unit via a first channel. The traffic between the remote node and the centralized unit may be carried on the wireless or the first channel. The RBS receives information about quality and capacity of the wireless channel and information on quantity and priority of upstream data traffic waiting to be transferred from the remote node to the centralized unit. Based on the information, the RBS determines that at least part of the upstream data traffic from the remote node should be carried on the wireless channel.

Abstract: A fuel cell stack assembly comprises a stack of fuel cells, each fuel cell having a cooling air conduit with an input/output ventilation aperture disposed on a ventilation face of the stack. The ventilation apertures form an array over said ventilation face of the stack. A first fan is configured to direct air flow through a first portion of the ventilation face and a second fan is configured to direct air flow through a second portion of the ventilation face. A reconfigurable plenum is in fluid communication with the first fan and the second fan and has a first configuration in which air is directed, by the first and second fans, through the first and second portions of the ventilation face in the same direction, and a second configuration in which air is directed, by at least one of the fans, respectively through the first and second portions of the ventilation face in opposing directions.

Abstract: A method of starting operation of a fuel cell system which includes at least a fuel cell stack the method includes opening an anode inlet valve to allow fuel to enter an anode volume of the fuel cell stack; then operating an air compressor in fluid communication with a cathode air inlet of the fuel cell stack to allow air to enter a cathode volume of the fuel cell stack monitoring the temperature of the cathode inlet and/or outlet operating a water injection system to inject water into the cathode volume once the temperature of fluid passing through the cathode inlet and/or outlet exceeds a preset level, wherein a current drawn from the fuel cell stack is limited to prevent a voltage measured across one or more cells in the fuel cell stack from falling below a first voltage threshold.

Abstract: A current collector component (206) for a fuel cell. The current collector component (206) comprises a first electrically conductive plate (210) configured to form a wall of a fluid confinement volume of a fuel cell; and a second electrically conductive plate (212) in electrical contact with the first electrically conductive plate (210). The second electrically conductive plate (212) comprises an external electrical connection (208). The second electrically conductive plate (212) has a higher electrical conductivity than the first electrically conductive plate (210). The first electrically conductive plate (210) has a higher resistance to corrosion than the second electrically conductive plate (212).

Abstract: A bipolar plate for a fuel cell, the bipolar plate comprising an anode sheet defining an anode surface and a cathode sheet defining a cathode surface. A cavity is defined between the anode sheet and the cathode sheet. One or more openings are provided in the cathode sheet and extend between the cathode surface and the cavity. The cavity is configured to receive coolant/oxidant for cooling the anode and cathode sheets and also provide at least a portion of the coolant/oxidant to the exterior of the cathode sheet through the one or more openings.

Abstract: A fuel cell assembly comprising a plurality of fuel cell plates in a stack. The stack defines an air inlet face and/or an air outlet face; and two opposing engagement faces. The fuel cell assembly also comprises a detachable cover configured to releasably engage the two engagement faces in order to define an air chamber with the air inlet or outlet face.

Abstract: A method of assembling a fuel cell plate assembly, the method comprising: placing a bipolar plate on a build point platform (1602); placing a prefabricated first fluid diffusion layer on, and in alignment with, the bipolar plate (1606); dispensing a first track of adhesive adjacent both the bipolar plate and a peripheral edge of the first fluid diffusion layer (1610); and, placing a prefabricated MEA and second fluid diffusion layer in sealing engagement with the first track of adhesive and thereby forming a seal between the bipolar plate, the peripheral edge of the first fluid diffusion layer and the MEA and second fluid diffusion layer (1612) wherein the method comprises lowering the build point platform (1604, 1608) before or after any or all of the placing or dispensing steps (1302, 1606, 1610, 1612).

Abstract: A mechanism for transferring a flexible sheet material (202) from a first substrate (203) to a second substrate (204) is disclosed, the mechanism having a head rotatable and translatable relative to the first and second substrates, the head (201) comprising a cylindrical curved portion (205) having an outer face (207) across which are provided openings (206) configured to apply air pressure to sheet material (202) contacting the outer surface (207) such that the head (201) is adapted to transfer the sheet material (202) from the first substrate (203) to the second substrate (204) by a combination of rotation and translation of the head (201).

Abstract: A method provides advertisements to optical network units (ONUs) by an optical line terminal (OLT), wherein the advertisements enable the ONUs to identify free channels from a plurality of wavelength-division multiplexing (WDM) channels in a passive optical network (PON). The method includes: transmitting from the OLT to the ONUs an advertisement identifying a free channel for each of a plurality of incompatible channel (ICH) groups, receiving a request from an ONU for the advertised free channel of an ICH group, authenticating the requesting ONU via the advertised free channel, allocating the advertised free channel to the requesting ONU upon successful authentication of the requesting ONU, and transmitting an updated advertisement from the OLT to the ONUs.

Abstract: The embodiments herein relate to a method in an optical network unit, referred to as an ONU, for providing wireless connectivity capability to the ONU. The ONU is comprised in a communications network. The ONU is interconnected to an optical line terminal, referred to as an OLT, via a wireline communications link and a wireless communications link. The ONU is configured to support a sleep mode. The ONU obtains information about entry into the sleep mode. The ONU identifies whether the wireless communications link is activated or deactivated, and activates the wireless communications link if the wireless communications link is identified as deactivated. The ONU enters sleep mode, and provides wireless connectivity capability to the ONU by means of the wireless communications link during the sleep mode.

Abstract: A fuel cell stack (100) comprising a plurality of fuel cell assemblies (102) adjacent to one another. The fuel cell assemblies each comprise an extended portion (104, 106, 108) having an aperture (110, 112, 114) therein. The aperture (110, 112, 114) is configured to provide a fluid connection to a fluid flow channel of the fuel cell assembly (102). The fuel cell stack (100) also comprises a clip (120, 122, 124) located over and around at least part of the extended portions (104, 106, 108) of the plurality of the fuel cell assemblies (102). The clip (120, 122, 124) is configured to resist outward expansion of the extended portions (104, 106, 108).

Abstract: A fuel cell plate assembly (400) comprising: a bipolar plate (102) having a port (104) for receiving a fluid; a fluid diffusion layer (210); and an electrode defining an active area (105). The fluid diffusion layer is configured to communicate a fluid received at the port (104) to the active area (105).

Abstract: A fuel cell stack assembly comprises a plurality of fuel cells in a stack, the stack defining two opposing parallel end faces. An end plate assembly is provided at each opposing end face of the stack. The end plate assemblies are coupled together to thereby maintain the fuel cells in the stack under compression. At least one of the end plate assemblies comprises: a master plate defining a master compression face having a first portion and a second portion; a first slave plate defining a first slave compression face; and a second slave plate defining a second slave compression face. The first slave compression face faces the first portion of the master compression face and when assembled, is in compressive relationship therewith, and the second slave compression face faces the second portion of the master compression face and when assembled, is also in compressive relationship therewith.

Abstract: Methods and apparatus for a network element or server end station to determine an estimated physical location of a fault in a communications link utilized by two network elements. In an embodiment, the first and second network elements generate link failure indications including time values representing when the respective network element detected the fault. In other embodiments, the link failure indications include time values transmitted over the communications link between the first and second network elements. A time distance between these time values is calculated, which is used to calculate the estimated physical location of the fault. In some embodiments, the link failure indications include sequence numbers transmitted or about to be transmitted over the communications link between the network elements. Sequence distances are calculated between the sequence numbers, and are used to calculate the estimated physical location of the fault.

Abstract: A fuel cell stack assembly comprises a plurality of fuel cells in a stack, the stack defining two opposing parallel end faces. An end plate is disposed at each opposing end face of the stack. Each end plate defines a compression surface adjacent to and in compressive relationship with a respective one of the two opposing parallel end faces. A coupling mechanism is attached to the end plates to thereby maintain the fuel cells in the stack under compression. At least one, preferably both, of the end plates comprise a preformed element defining the compression surface, the preformed element being configured with a predetermined curvature such that the compression surface is a convex surface when the preformed element is not under load whereas, under the application of the load to maintain the fuel cells under compression, flexure of the preformed element between elements of the coupling mechanism causes the compression surface to become a substantially planar surface.