Charge control of a metal-air battery

1 : A method for managing charge of a metal-air battery comprising at least one cell, the at least one cell comprising at least a negative electrode, a first positive air electrode, and a second positive oxygen-release electrode, the method comprising, for each cell, during application of a current to the at least one cell that results, during charging, in the flow of charging current between the negative electrode and the second positive oxygen-release electrode: comparing an absolute value of a potential of the negative electrode to a critical threshold value, the potential of the negative electrode being determined relative to the first positive air electrode; when the absolute value of the potential of the negative electrode reaches the critical threshold value, diverting an excess charging current that is a function of a difference between a current applied to the at least one cell and the charging current. 2 : The method of claim 1 , wherein the excess charging current of the at least one cell is diverted to a neighboring cell or to a charger. 3 : The method of claim 1 , wherein, for each cell, the critical threshold value is set based on the potential of the negative electrode when charging begins. 4 : The method of claim 1 , wherein the critical threshold value is re-evaluated at regular time intervals. 5 : The method of claim 1 , wherein an analog circuit comprising a component of variable impedance is provided, the diverting of excess charging current being implemented by modifying impedance of said component of variable impedance. 6 : The method of claim 5 , wherein the impedance of the component of variable impedance varies at least as a function of a quantity representative of a difference between the potential of the negative electrode and said critical threshold value, in order to deliver said excess charging current as output from the component of variable impedance. 7 : The method of claim 1 , wherein measurement of the potential of the negative electrode comprises voltage stabilization filtering between the negative electrode and the first air electrode. 8 : A charge manager for a cell of a metal-air battery comprising at least one cell, the cell comprising at least a negative electrode, a first positive air electrode, and a second positive oxygen-release electrode, the charge manager comprising an electronic circuit for each cell, arranged so as to, during application of a current to the cell that results, during charging, in the flow of charging current between the negative electrode and the second positive oxygen-release electrode: comparing an absolute value of a potential of the negative electrode to a critical threshold value, the potential of the negative electrode being determined relative to the first positive air electrode; when the absolute value of the potential of the negative electrode reaches the threshold value, diverting an excess charging current that is a function of difference between current applied to the cell and the charging current. 9 : The charge manager of claim 8 , wherein the electronic circuit diverts the excess charging current to a neighboring cell or to a charger, via a respective connection to said neighboring cell or charger. 10 : The charge manager of claim 8 , wherein the electronic circuit comprises a component of variable impedance, the diverting of the excess charging current being implemented by changing the impedance of said component of variable impedance. 11 : The charge manager of claim 10 , wherein the component of variable impedance is a power transistor. 12 : The charge manager of claim 11 , wherein the power transistor is a Darlington transistor. 13 : The charge manager of claim 9 , further comprising an electronic circuit for measuring the difference in potential between the negative electrode and the first positive air electrode. 14 : The charge manager of claim 13 , wherein the electronic measurement circuit comprises a voltage stabilization filter. 15 : A battery comprising at least one cell, the at least one cell comprising at least a negative electrode, a first positive air electrode, a second positive oxygen-release electrode, and the charge manager of claim 8 .