Cathode for a metal/air battery and methods for manufacturing such a cathode

What is claimed is: 1. A cathode for a metal/air battery comprising at least one active layer which is produced in an active material and has an air side and a metal side, a current collector, and a hydrophobic membrane produced in a hydrophobic material and deposited on the air side of the active layer, wherein said hydrophobic material has a porous structure and wherein said hydrophobic material has penetrated into the air side of the active layer so as to form, between the hydrophobic membrane and the active layer, an interpenetration zone of hydrophobic material in the active material, in which there is a concentration gradient of hydrophobic material which decreases in the ingoing direction of air into the cathode. 2. The cathode according to claim 1 , wherein the porous structure of the hydrophobic material has the form of a matrix of fibrils interconnecting solid nodes, the space between the nodes and the fibrils forming microscopic pores. 3. The cathode according to claim 1 , wherein the hydrophobic membrane has a density between 0.2 g/cm 3 and 0.5 g/cm 3 . 4. The cathode according to claim 2 , wherein the microscopic pores have an average size between 30 and 100 μm. 5. The cathode according to claim 3 , wherein the microscopic pores have an average size between 30 and 100 μm. 6. The cathode according to claim 1 , wherein the hydrophobic material is a fluorinated polymer which is extruded then expanded. 7. The cathode according to claim 1 , wherein the concentration of hydrophobic material in the interpenetration zone changes from 100% to 0% in the ingoing direction of air into the cathode, the interpenetration zone extending over a thickness between 10 and 25% of the total thickness of the active layer. 8. The cathode according to claim 1 , wherein the active material comprises at least one binder, one catalyst and conductive particles. 9. A method for manufacturing a cathode for the metal/air battery comprising at least one active layer which is produced in an active material and has an air side and a metal side, a current collector, and a hydrophobic membrane produced in a hydrophobic material and deposited on the air side of the active layer, said hydrophobic material having a porous structure and said hydrophobic material having penetrated into the air side of the active layer so as to form, between the hydrophobic membrane and the active layer, an interpenetration zone of hydrophobic material in the active material, in which there is a concentration gradient of hydrophobic material which decreases in the ingoing direction of air into the cathode, said method comprising the steps of: a) preparing the active material of the active layer in the form of a paste, b) depositing the paste obtained in step a) on the current collector c) depositing a hydrophobic membrane produced in a hydrophobic material which has a porous structure on the paste as obtained in step b) d) applying a pressure over the assembly obtained in step c), so as to form, between the hydrophobic membrane and the active layer, an interpenetration zone of hydrophobic material in the active material, in which there is a concentration gradient of hydrophobic material which decreases in the ingoing direction of air into the cathode. 10. The method according to claim 9 , wherein the pressure applied in step d) is less than or equal to a pressure corresponding to a linear load of 150 N/mm. 11. A method for manufacturing a cathode for the metal/air battery comprising at least one active layer which is produced in an active material and has an air side and a metal side, a current collector, and a hydrophobic membrane produced in a hydrophobic material and deposited on the air side of the active layer, said hydrophobic material having a porous structure and said hydrophobic material having penetrated into the air side of the active layer so as to form, between the hydrophobic membrane and the active layer, an interpenetration zone of hydrophobic material in the active material, in which there is a concentration gradient of hydrophobic material which decreases in the ingoing direction of air into the cathode, said method comprising the steps of: a′) preparing the active material of the active layer in the form of a paste b′) depositing a first layer of the paste obtained in step a′) over the current collector c′) applying a pressure over the assembly obtained in step b′) d′) depositing a second layer of paste on the assembly obtained in step c′) e′) depositing a hydrophobic membrane produced in a hydrophobic material which has a porous structure on the second layer of paste as obtained in step d′) f′) applying a pressure over the assembly obtained in step e′), so as to form, between the hydrophobic membrane and the active layer, an interpenetration zone of hydrophobic material in the active material, in which there is a concentration gradient of hydrophobic material which decreases in the ingoing direction of air into the cathode. 12. The method according to claim 11 , wherein the pressure applied in step c′) corresponds to a linear load between 250 N/mm and 500 N/mm. 13. The method according to claim 11 , wherein the pressure applied in step f′) is less than or equal to a pressure corresponding to a linear load of 150 N/mm. 14. A manufacturing method according to claim 9 , wherein it comprises a step of drying the cathode. 15. A manufacturing method according to claim 11 , wherein it comprises a step of drying the cathode. 16. A metal/air battery comprising at least one anode based on said metal, a cathode comprising at least one active layer which is produced in an active material and has an air side and a metal side, a current collector, and a hydrophobic membrane produced in a hydrophobic material and deposited on the air side of the active layer, said hydrophobic material having a porous structure and said hydrophobic material having penetrated into the air side of the active layer so as to form, between the hydrophobic membrane and the active layer, an interpenetration zone of hydrophobic material in the active material, in which there is a concentration gradient of hydrophobic material which decreases in the ingoing direction of air into the cathode, and an electrolyte.