Determining a spatial distribution of a thermal conductivity of an electrochemical cell

1 . Method for determining a spatial distribution (Rh x,y f ) of a parameter of interest (Rh) representative of heat removal within a bipolar plate of an electrochemical cell, said cell including two electrodes separated from each other by an electrolyte and placed between bipolar plates suitable for bringing reactive species to the electrodes and for removing the heat produced by the cell in operation, the bipolar plates being formed from two sheets that are bonded to each other, each sheet including embossments forming, in what is called an external face, a circuit for distributing a reactive species, the embossments of the sheets together forming, in what are called internal faces that are opposite the external faces, a cooling circuit including cooling channels that communicate fluidically with one another between an inlet and an outlet of the cooling circuit, comprising: i) providing an electrochemical cell, within which the parameter of interest (Rh) is distributed with an initial spatial distribution (Rh x,y f ) and for which the spatial distribution of a temperature within the electrochemical cell in operation has at least one local value higher than or equal to a preset maximum local value; ii) defining a spatial distribution (T x,y c ) of a set-point temperature (T c ) within the cell in operation, said distribution being such that the local temperature values are lower than preset maximum local values; iii) measuring a spatial distribution (Q x,y r ) of a first thermal quantity (Q r ) representative of a local production of thermal energy within said electrochemical cell in operation; iv) estimating a spatial distribution (D x,y e ) of a second thermal quantity (D e ) representative of a local flow rate of a heat-transfer fluid in a cooling circuit of a bipolar plate of the electrochemical cell in operation, depending on said spatial distribution (T x,y c ) of the set-point temperature (T c ) and on said spatial distribution (Q x,y r ) of the first thermal quantity (Q r ), so that the spatial distribution of the temperature of said electrochemical cell in operation, the first thermal quantity (Q r ) of which cell having said measured spatial distribution (Q x,y r ) and the second thermal quantity (D e ) of which cell having said estimated spatial distribution (D x,y e ), is substantially equal to that (T x,y c ) of the set-point temperature (T c ); and v) determining a spatial distribution (Rh x,y f ) of the parameter of interest (Rh) depending on the estimated spatial distribution (D x,y e ) of the second thermal quantity (D c ). 2 . Determining method according to claim 1 , wherein the parameter of interest is a hydraulic resistance (Rh) or a geometric coefficient (ζ) of minor head losses within a cooling circuit of at least one of the bipolar plates, through which circuit a heat-transfer fluid is intended to flow. 3 . Determining method according to claim 1 , wherein determining the spatial distribution of the parameter of interest is furthermore carried out depending on a preset overall electrical power value of the electrochemical cell. 4 . Determining method according to claim 1 , wherein estimating a spatial distribution of the second thermal quantity includes: generating a mesh of a cooling circuit of at least one bipolar plate of the electrochemical cell, through which circuit a heat-transfer fluid is intended to flow; and simulating numerically by computer the second thermal quantity on said mesh, by solving a discrete numerical model relating the second thermal quantity to the local temperature and to the first thermal quantity. 5 . Determining method according to claim 1 , wherein the first thermal quantity is representative of a production of thermal energy (Q r ) within the cell in operation, and the second thermal quantity is representative of a flow rate (D c ) of a heat-transfer fluid through a cooling circuit of a bipolar plate of the cell. 6 . Determining method according to claim 5 , wherein, in iv), the spatial distribution (D x,y e ) of the flow rate (D e ) of the heat-transfer fluid allowing said produced heat (Q r ) to be removed is estimated depending on the spatial distribution (Q x,y r ) so as to obtain said spatial distribution (T x,y c ) of the set-point temperature (T c ). 7 . Determining method according to claim 6 , wherein, in v), the spatial distribution (Rh x,y f ) of the parameter of interest (Rh) is determined so that the flow rate of the heat-transfer fluid through the cooling circuit has the spatial distribution (D x,y e ) estimated beforehand. 8 . Method for producing an electrochemical-cell bipolar plate, comprising: considering a reference electrochemical cell, said cell including two electrodes separated from each other by an electrolyte and placed between bipolar plates suitable for bringing reactive species to the electrodes and for removing the heat produced by the cell in operation via a cooling circuit through which a heat-transfer fluid is intended to flow, the cooling circuit having a parameter of interest (Rh) representative of a hydraulic resistance (Rh) or a geometric coefficient (ζ) of minor head losses, said parameter being spatially distributed with an initial distribution (Rh x,y i ); determining a spatial distribution (Rh x,y f ) of the parameter of interest (Rh), using the method ( 100 ; 200 ) according to claim 1 ; and producing said bipolar plate in such a way that the parameter of interest (Rh) has the determined spatial distribution (Rh x,y f ). 9 . Method for producing a bipolar plate according to claim 8 , wherein an insert is added to at least one duct of the cooling circuit, said insert having a thickness transverse to a longitudinal axis of said duct suitable for locally increasing the hydraulic resistance of the duct. 10 . Method for producing a bipolar plate according to claim 8 , wherein an insert is added to at least one duct of the cooling circuit, said insert being formed from at least one plate section of substantially constant thickness, including at least one embossment suitable for locally creating a minor head loss. 11 . Method for producing an electrochemical cell including two electrodes separated from each other by an electrolyte and placed between two bipolar plates suitable for bringing reactive species to the electrodes and for removing the heat produced by the cell in operation, comprising: considering a reference electrochemical cell having a parameter of interest (Rh) representative of the electrical power production of the cell and distributed with an initial spatial distribution (Rh x,y i ); determining a spatial distribution (Rh x,y f ) of the parameter of interest (Rh) using the determining method according to claim 1 ; and producing the electrochemical cell, on the basis of the reference electrochemical cell in which the parameter of interest (Rh) has the determined spatial distribution (Rh x,y f ). 12 . Data storage medium containing instructions for implementing the determining method according to claim 1 , these instructions being executable by a processor. 13 . Method for producing a bipolar plate according to claim 9 , wherein an insert is added to at least one duct of the cooling circuit, said insert being formed from at least one plate section of substantially constant thickness, including at least one embossment suitable for locally creating a minor head loss.