Anode bleed control in a fuel cell stack

The invention claimed is: 1. And electrochemical fuel cell assembly comprising: a fuel cell stack having a fuel delivery inlet and a fuel delivery outlet, the fuel cell stack further comprising a number of fuel cells each having a membrane-electrode assembly and a fluid flow path coupled between the fuel delivery inlet and the fuel delivery outlet for delivery of fuel to the membrane-electrode assembly; a fuel delivery conduit coupled to the fuel delivery inlet for delivery of fluid fuel to the stack; a bleed conduit coupled to the fuel delivery outlet for venting fluid out of the stack; a variable orifice flow control device coupled to the bleed conduit configured to dynamically vary an amount of fluid from the fuel delivery outlet passing into the bleed conduit as a function of one or more of the control parameters: (i) measured fuel concentration; (ii) measured humidity; (iii) cell voltages of fuel cells in the stack; (iv) impedance of fuel cells in the stack; (v) resistance of fuel cells in the stack; and, in which the recirculation conduit includes one or both of: a water separator configured to extract liquid water from the fuel circuit; a condenser configured to extract water vapour from the fuel circuit, and in which the variable orifice flow control device is further configured to dynamically vary the proportion of fluid passing into the bleed conduit as a function of the quantity of water and/or water vapour being extracted from the fuel circuit. 2. An electrochemical fuel cell assembly comprising: a fuel cell stack having a fuel delivery inlet and a fuel delivery outlet, the fuel cell stack further comprising a number of fuel cells each having a membrane-electrode assembly and a fluid flow path coupled between the fuel delivery inlet and the fuel delivery outlet for delivery of fuel to the membrane-electrode assembly; a fuel delivery conduit coupled to the fuel delivery inlet for delivery of fluid fuel to the stack; a bleed conduit coupled to the fuel delivery outlet for venting fluid out of the stack; a variable orifice flow control device coupled to the bleed conduit configured to dynamically vary an amount of fluid from the fuel delivery outlet passing into the bleed conduit as a function of one or more of the control parameters: (i) measured fuel concentration; (ii) measured humidity; (iii) cell voltages of fuel cells in the stack; (iv) impedance of fuel cells in the stack; (v) resistance of fuel cells in the stack; a recirculation conduit coupled between the fuel delivery outlet and the fuel delivery conduit for recirculating fluid from the fuel delivery outlet to the fuel delivery inlet, the fuel delivery conduit, the recirculation conduit and the fuel flow paths in the fuel cell stack together defining a fuel circuit; wherein the variable orifice flow control device is coupled to the recirculation conduit and is configured to dynamically vary a proportion of fluid from the fuel delivery outlet passing into the bleed conduit as a function of the control parameters, wherein the recirculation conduit is coupled to the fuel delivery conduit by way of an ejector in the fuel delivery conduit, the recirculation conduit being coupled to a suction port of the ejector and the fuel delivery inlet being coupled to a discharge port of the ejector; and, in which the ejector is a variable orifice ejector. 3. An electrochemical fuel cell assembly comprising: a fuel cell stack having a fuel delivery inlet and a fuel delivery outlet, the fuel cell stack further comprising a number of fuel cells each having a membrane-electrode assembly and a fluid flow path coupled between the fuel delivery inlet and the fuel delivery outlet for delivery of fuel to the membrane-electrode assembly; a fuel delivery conduit coupled to the fuel delivery inlet for delivery of fluid fuel to the stack; a bleed conduit coupled to the fuel delivery outlet for venting fluid out of the stack; a variable orifice flow control device coupled to the bleed conduit configured to dynamically vary an amount of fluid from the fuel delivery outlet passing into the bleed conduit as a function of one or more of the control parameters: (i) measured fuel concentration; (ii) measured humidity; (iii) cell voltages of fuel cells in the stack; (iv) impedance of fuel cells in the stack; (v) resistance of fuel cells in the stack; a recirculation conduit coupled between the fuel delivery outlet and the fuel delivery conduit for recirculating fluid from the fuel delivery outlet to the fuel delivery inlet, the fuel delivery conduit, the recirculation conduit and the fuel flow paths in the fuel cell stack together defining a fuel circuit; wherein the variable orifice flow control device is coupled to the recirculation conduit and is configured to dynamically vary a proportion of fluid from the fuel delivery outlet passing into the bleed conduit as a function of the control parameters; in which the recirculation conduit is coupled to the fuel delivery conduit by way of an ejector in the fuel delivery conduit, the recirculation conduit being coupled to a suction port of the ejector and the fuel delivery inlet being coupled to a discharge port of the ejector; in which the ejector is a variable orifice ejector; and, having a humidity sensor, a temperature sensor and a pressure sensor in the fuel delivery conduit between the discharge port of the ejector and the fuel delivery inlet. 4. The electrochemical fuel cell assembly of claim 1 in which the variable orifice flow control device further includes a controller configured to vary the flow of fluid through the flow control device to the bleed conduit so as to maximise fuel utilisation efficiency. 5. An electrochemical fuel cell assembly comprising: a fuel cell stack having a fuel delivery inlet and a fuel delivery outlet, the fuel cell stack further comprising a number of fuel cells each having a membrane-electrode assembly and a fluid flow path coupled between the fuel delivery inlet and the fuel delivery outlet for delivery of fuel to the membrane-electrode assembly; a fuel delivery conduit coupled to the fuel delivery inlet for delivery of fluid fuel to the stack; a bleed conduit coupled to the fuel delivery outlet for venting fluid out of the stack; a variable orifice flow control device coupled to the bleed conduit configured to dynamically vary an amount of fluid from the fuel delivery outlet passing into the bleed conduit as a function of one or more of the control parameters: (i) measured fuel concentration; (ii) measured humidity; (iii) cell voltages of fuel cells in the stack; (iv) impedance of fuel cells in the stack; (v) resistance of fuel cells in the stack; a recirculation conduit coupled between the fuel delivery outlet and the fuel delivery conduit for recirculating fluid from the fuel delivery outlet to the fuel delivery inlet, the fuel delivery conduit, the recirculation conduit and the fuel flow paths in the fuel cell stack together defining a fuel circuit; wherein the variable orifice flow control device is coupled to the recirculation conduit and is configured to dynamically vary a proportion of fluid from the fuel delivery outlet passing into the bleed conduit as a function of the control parameters; in which the recirculation conduit is coupled to the fuel delivery conduit by way of an ejector in the fuel delivery conduit, the recirculation conduit being coupled to a suction port of the ejector and the fuel delivery inlet being coupled to a discharge port of the ejector; and, the recirculation conduit includes one or both of: (i) a water separator configured to extract liquid water from the fuel circuit; (ii) a condenser configured to extract water vapour from the fuel circuit, the fuel cell assembly further including a controller configured to modulate discharge pressu