Fuel cell component having dimensions selected to maximize a useful area

We claim: 1. A fuel cell component, comprising: a generally planar body having a total area defined by a length and a width of the body; a cooling portion of the total area being occupied by a cooling feature that renders the cooling portion unusable for at least one fuel cell function, the cooling portion of the total area including two triangular regions of the total area; a sealing portion of the total area being occupied by a sealing feature that renders the sealing portion unusable for the at least one fuel cell function; and an active portion of the total area being an active area of the component that is useable for the at least one fuel cell function, and wherein the active area of the component includes a reactant flow field having a plurality of channels that extend straight from a first edge of the body to a second edge of the body opposite to the first edge of the body, and that extend at an oblique angle to the first and second edges of the body. 2. The fuel cell component of claim 1 , wherein an aspect ratio of the length to the width is equal to one plus a first dimension of the cooling portion in a direction aligned with the first and second edges of the body divided by twice a second dimension of the sealing portion in the direction aligned with the first and second edges of the body. 3. The fuel cell component of claim 2 , wherein: the fuel cell component comprises a fluid transport plate assembly; the cooling feature comprises a portion of the plate assembly configured for directing flow of a fuel cell coolant into or out of the plate assembly; and the sealing feature comprises a seal assembly configured for sealing edges of the plate assembly. 4. The fuel cell component of claim 3 , wherein the aspect ratio provides a maximum of the active area on the plate assembly given the length and the width and the first and second dimensions. 5. The fuel cell component of claim 2 , wherein the aspect ratio provides a maximum of the active area on the component given the length and the width and the first and second dimensions. 6. A method of making a fuel cell component, comprising: determining a first dimension of a cooling portion of a total area of the component that has to be occupied by a cooling feature that renders the cooling portion unusable for at least one fuel cell function, the cooling portion of the total area including two triangular regions of the total area; determining a second dimension of a sealing portion of the total area that has to be occupied by a sealing feature that renders the sealing portion unusable for the at least one fuel cell function; selecting a total length and a total width of the component to establish an aspect ratio of the total length to the total width; manufacturing the fuel cell component to have the determined first and second dimensions and the selected total length and total width, and to have an active area that is useable for the at least one fuel cell function, the active area including a reactant flow field having a plurality of channels that extend straight from a first edge of the component aligned with the first and second dimensions to a second edge of the component aligned with the first and second dimensions and opposite to the first edge of the component, and that extend at an oblique angle to the first and second edges of the component. 7. The method of claim 6 , wherein the aspect ratio is equal to one plus the first dimension divided by twice the second dimension. 8. The method of claim 7 , wherein: the fuel cell component comprises a fluid transport plate assembly; the cooling feature comprises a portion of the plate assembly configured for directing flow of a fuel cell coolant into or out of the plate assembly; the sealing feature comprises a seal configured for sealing edges of the plate assembly; and the at least one fuel cell function comprises directing flow of fuel cell reactants such that an electrochemical reaction can occur. 9. The method of claim 8 , comprising selecting the total length and the total width to maximize the active area of the component that is useable for the at least one fuel cell function given the total length and the total width and the first and second dimensions. 10. The method of claim 6 , comprising selecting the total length and the total width to maximize the active area of the component that is useable for the at least one fuel cell function given the total length and the total width and the first and second dimensions. 11. The method of claim 6 wherein manufacturing the fuel cell component includes gang milling the plurality of channels. 12. The fuel cell component of claim 1 wherein: the component includes a bipolar fuel cell plate; the plurality of channels includes a plurality of reactant channels formed on a first major surface of the plate; and the plate includes a plurality of coolant channels formed on a second major surface of the plate opposite to the first major surface of the plate. 13. The fuel cell component of claim 1 wherein a first one of the two triangular regions includes a coolant inlet and a second one of the two triangular regions includes a coolant outlet. 14. The fuel cell component of claim 13 wherein the fuel cell component is rotationally symmetric. 15. The fuel cell component of claim 1 wherein the active area of the component has a shape comprising a parallelogram.