Bipolar lithium-ion battery

1 : A bipolar lithium-ion battery comprising n electrochemical cells connected in series, n being an integer higher than or equal to 2, each electrochemical cell comprising: a positive electrode, a current collector carrying the positive electrode, a negative electrode, a current collector carrying the negative electrode, an electrolyte disposed between each pair of positive and negative electrodes, n−1 current collectors, called common current collectors, each one made as a single piece with the current collector of an adjacent cell, the common current collectors carrying an electrode of each polarity, the n−1 comprising a material comprising carbon fibres, a shell receiving all the electrochemical cells and defining for each of them a compartment being tight with respect to the compartments of the other electrochemical cells, said compartments being flexible. 2 : The bipolar battery according to claim 1 , wherein all the current collectors comprise carbon fibres. 3 : The bipolar battery according to claim 1 , wherein the n−1 common collectors comprise a negative electrode zone with a surface area at least equal to the surface area of the negative electrode, a positive electrode zone with a surface area at least equal to the surface area of the positive electrode and a connection zone with a reduced surface area between the negative electrode zone and the positive electrode zone. 4 : The bipolar battery according to claim 1 , wherein the positive electrodes comprise LiFePO 4 , LiNi 0.33 Mn 0.33 Co 0.33 O 2 , LiNi x Co y Al z O 2 with x+y+z=1, LiMnO 2 , LiNiO 2 or of LiNi 0.4-0.5 Mn 1.5-1.6 O 4 . 5 : The bipolar battery according to claim 1 , wherein the negative electrodes comprise titanate (Li 4 Ti 5 O 12 ), silicon, silicon carbide. 6 : The bipolar battery according to claim 1 , wherein the negative electrodes are directly formed by current collector zones facing a positive electrode. 7 : A method for manufacturing a bipolar battery according to claim 1 , comprising: a) providing two unit collectors of electrically conductive material and n−1 common current collectors of carbon fibres, b) making a negative electrode on a unit current collector, c) making a positive electrode on another unit current collector, d) making a negative electrode on a zone of the n−1 common current collectors and a positive electrode on another zone of the n−1 common current collectors, e) facing n−2 positive electrodes carried by n−2 common current collectors with a negative electrode of the n−2 common collectors and facing a remaining positive electrode carried by a common current collector with the negative electrode of a unit current collector and a remaining negative electrode of a common current collector with the positive electrode of the other unit current collector, f) placing an electrolyte between each facing pair of positive and negative electrodes, g) placing the electrochemical cells in at least one shell and tightly separating the electrochemical cells and sealing said at least one shell so as to make a tight compartment for each electrochemical cell. 8 : The manufacturing method according to claim 7 , wherein step f) is made after placing the electrochemical cells in the shell and before sealing the shell. 9 : The manufacturing method according to claim 7 , wherein the shell is heat-sealable and heat-sealable tapes are disposed on the common current collectors in the zone between the positive and negative electrodes and a heat application on the heat-sealable tapes occurs. 10 : The manufacturing method according to claim 7 , wherein the positive electrodes and/or the negative electrodes are made by printing. 11 : The manufacturing method according to claim 10 , wherein during printing, a suction occurs. 12 : The manufacturing method according to claim 7 , wherein the positive electrodes and/or the negative electrodes are made by screen printing. 13 : The manufacturing method according to claim 12 , wherein during screen printing, a suction occurs.