Process for supplying a fuel cell having alternate supply and purge phases

The invention claimed is: 1. A process for supplying a fuel cell comprising a stack of electrochemical cells divided into N groups of cells, where N≥2, with reactive species diluted in a carrier gas, the process comprising: (I) supplying a selected group of cells from the N groups with the reactive species diluted in the carrier gas, wherein the reactive species not consumed in the selected group of cells circulates in the other groups of cells via distribution lines that ensure fluidic communication among the N groups of cells and that are arranged so as to form a fluidic pathway for the reactive species to go from the selected group of cells to one or more last groups of cells forming an end of the fluidic pathway, (II) purging the N groups of cells after the supplying (I) by simultaneously supplying each of the N groups of cells with the reactive species, wherein each group of cells communicates with an outlet orifice of the fuel cell that enables fluidic discharging of the N groups of cells, and (III) subsequently repeating the supplying (I) followed by the purging (II) so that the purging (II) is performed between two successive supplyings (I), wherein selected groups of cells in the two successive supplyings (I) are different. 2. The process according to claim 1 , wherein the fluidic distribution lines are arranged with respect to the N groups of cells so that a direction of fluidic flow of the reactive species in the one or more last groups of cells during the supplying (I) is identical to a direction of fluidic flow in the same groups of cells during the following purging (II). 3. The process according to claim 1 , wherein the fluidic distribution lines are arranged with respect to the N groups of cells so that a direction of fluidic flow of the reactive species in each of the N groups during the supplying (I) is identical to a direction of fluidic flow in each of the same groups during the following purging (II). 4. The process according to claim 1 , wherein the fluidic distribution lines are arranged with respect to the N groups of cells so that a direction of fluidic flow of the reactive species in the one or more last groups of cells during the purging (II) is identical to a direction of fluidic flow in the same groups of cells during the following supplying (I). 5. The process according to claim 1 , wherein the fluidic distribution lines are arranged with respect to the N groups of cells so that a direction of fluidic flow of the reactive species in each of the N groups during the purging (II) is identical to a direction of fluidic flow in each of the same groups during the following supplying (I). 6. The process according to claim 1 , wherein the electrochemical cells each comprise an anode and cathode, and the cathodes and/or the anodes of the stack of electrochemical cells are supplied with the reactive species diluted in the carrier fluid. 7. The process according to claim 6 , wherein the cathodes are supplied with atmospheric air containing oxygen. 8. The process according to claim 1 , wherein, during the purging (II), the reactive species has different molar flow rates at inlets of at least two of the N groups of cells. 9. The process according to claim 8 , wherein, one of the at least two of the N groups of cells is a last group during the preceding supplying (I), which has a molar flow rate greater than that of at least one other group.