Fuel cell system and tail gas burner assembly and method

The invention claimed is: 1. A fuel cell system comprising a fuel cell stack and a burner assembly: the burner assembly comprising: (i) a hollow longitudinally elongate body extending along a central axis and having a first end and a second end, (ii) a burner wall located between said first end and said second end, and defining a first volume from said first end to said burner wall, and a second volume from said burner wall to said second end, (iii) an oxidant inlet into said first volume, said oxidant inlet for providing an oxidant flow therethrough, (iv) at least one hollow elongate burner abutting said burner wall or extending through an opening in said burner wall from said first volume to said second volume, and comprising: (a) a burner plate or mixer having a first side opening into said first volume, and a second side opening into said second volume, (b) a first fuel inlet into said first volume for feeding a first fuel from a first fuel passageway to said first volume; and (c) a second fuel inlet into said second volume for feeding a second fuel from a second fuel passageway to said second volume; wherein said fuel cell system further comprises: a first fuel source for supplying the first fuel to the first fuel passageway, the first fuel being a high calorific value fuel and neither a reformate gas from a reformer of the fuel cell system nor an anode off gas from an anode of the fuel cell stack; a second fuel source for supplying the second fuel to the second fuel passageway, the second fuel being a reformate gas from a reformer of the fuel cell system or an anode off gas from an anode of the fuel cell stack; and at least one connection upstream of the first fuel passageway and the second fuel passageway to selectively connect fuel from the first fuel supply also into said second fuel passageway such that said second fuel is mixed with high calorific value fuel that is neither a reformate gas from a reformer of the fuel cell system nor an anode off gas from an anode of the fuel cell stack, prior to delivery to said second fuel inlet. 2. The system of claim 1 , wherein said at least one connection comprises a three-way valve. 3. The system of claim 1 , wherein said at least one hollow elongate burner comprises said mixer, and said mixer is an axial swirl mixer comprising a plurality of vanes having a first side opening into said first volume, and a second side opening into said second volume. 4. The system of claim 1 , wherein said at least one hollow elongate burner comprises said burner plate, and said burner plate comprises a plurality of passageways extending between said first volume and said second volume. 5. The system of claim 1 , further comprising an off-gas pipe system connecting an outlet of an anode of a fuel cell stack to said second fuel inlet for delivery of said second fuel to said second fuel inlet, wherein said second fuel passageway forms part of said off-gas pipe system. 6. The system of claim 1 , further comprising a first gas pipe system connecting a fuel gas source to said first fuel inlet for delivery of said first fuel gas to said first fuel inlet, wherein said first fuel passageway forms part of said first gas pipe system and wherein said first fuel is any one or more of mains supplied gas, natural gas, start-up fuel and top-up fuel. 7. The system of claim 1 , wherein said connection comprises a bypass line that extends to said second fuel passageway for selectively diverting said first fuel from said first fuel inlet to said second fuel inlet. 8. The system of claim 1 , wherein at least one of said first fuel inlet and said second fuel inlet is an orifice in, respectively, said first fuel pipe or said second fuel pipe. 9. The system of claim 8 , wherein said first, and/or second, fuel inlet is not positioned at an end of its respective fuel passageway, but is positioned along its respective fuel passageway. 10. A fuel cell system comprising a fuel cell stack and a burner assembly, the burner assembly comprising: (i) a hollow longitudinally elongate body extending along a central axis and having a first end and a second end, (ii) a burner wall located between said first end and said second end, and defining a first volume from said first end to said burner wall, and a second volume from said burner wall to said second end, (iii) an oxidant inlet into said first volume, said oxidant inlet for providing an oxidant flow therethrough, (iv) at least one hollow elongate burner abutting said burner wall or extending through an opening in said burner wall from said first volume to said second volume, and comprising: (a) a burner plate or mixer having a first side opening into said first volume, and a second side opening into said second volume, (b) a first fuel inlet into said first volume; and (c) a second fuel inlet into said second volume; wherein said fuel cell system further comprises: a first fuel passageway containing a first fuel, the first fuel being a high calorific value fuel and neither a reformate gas from a reformer of the fuel cell system nor an anode off gas from an anode of the fuel cell stack, and the first fuel passageway being connected to the first fuel inlet; a second fuel passageway containing a second fuel, the second fuel being a reformate gas from a reformer of the fuel cell system or an anode off gas from an anode of the fuel cell stack, and the second fuel passageway being connected to the second fuel inlet, and at least one connection for selectively connecting the first fuel passageway and the second fuel passageway to mix fuel of said first fuel passageway with said second fuel in the second fuel passageway, such that said second fuel is mixed with high calorific value fuel that is neither a reformate gas from a reformer of the fuel cell system nor an anode off gas from an anode of the fuel cell stack, prior to delivery to said second fuel inlet. 11. A method of operating a fuel cell system according to claim 1 , said method comprising the steps of: (i) directing said oxidant flow to said oxidant inlet; (ii) selectively directing said first fuel from said first fuel source to said first fuel passageway and selectively directing said second fuel from said second fuel source to said second fuel passageway; and (iii) selectively combusting said selectively directed fuel or fuels in said second volume after exiting one of: a. said burner plate or mixer; b. said second fuel inlet; or c. said burner plate or mixer and said second fuel inlet. 12. The method of claim 11 , comprising use of said connection for selectively connecting said first fuel to said second fuel passageway for delivering a mixture of said first and second fuels to said second fuel inlet, whereby said mixture of said first and second fuels is combusted in said second volume after exiting said second fuel inlet. 13. The method according to claim 11 , wherein said fuel cell system is selectively operable in: (i) a first mode in which said first fuel is directed to said first fuel inlet via said first fuel passageway, said oxidant and said first fuel thus converging and mixing in said first volume between said first fuel inlet and said burner plate or mixer, and wherein said second fuel is not supplied to said second fuel inlet; (ii) a second mode in which said first fuel is directed to said first fuel inlet via said first fuel passageway, said oxidant and said first fuel thus converging and mixing in said first volume between said first fuel inlet and said burner plate or mixer, and said second fuel is supplied to said second fuel inlet, said oxidant and said second fuel thus converging and mixing in sai