Process and device for filling tanks with pressurized gas

What is claimed is: 1. A filling station for filling tanks with pressurized gas, comprising: at least one source of pressurized gas a fluid circuit for the transfer of the gas from the at least one source to the tanks that comprises a first end connected to the at least one source of pressurized gas, a second end provided with a transfer pipe intended to be joined in removable fashion to the tanks to be filled, a first isolation valve positioned between the first and second ends, a member for regulation of flow rate or pressure, a second isolation valve, and a pressure sensor disposed between the first and second isolation valves and an electronic data processing and storage member, wherein: the station is suitable for, and configured for, carrying out a filling of a first tank and then a filling of a second tank; the electronic data processing and storage member is adapted and configured to control the successive fillings and the first and second isolation valves and carry out a leak test between the filling of the first tank and the filling of the second tank during which the second tank is joined in leaktight fashion to the second end of the circuit; the leak test comprises the step of placing the second tank under pressure via an opening of the second isolation valve at the end of the filling of the first tank; the electronic data processing and storage member is configured to: a) close the first and second isolation valves in order to trap a supply of pressurized gas in the circuit between these two valves; b) cause performance of said leak test when the pressure of the trapped pressurized gas measured by the pressure sensor is greater than a predetermined threshold; and c) when the pressure of the trapped pressurized gas measured by the pressure sensor is lower than the predetermined threshold, cause the first isolation valve to open in order to fill the circuit between the first and second isolation valves with the pressurized gas from the at least one source of pressurized gas until the predetermined threshold is reached or exceeded; and d) subsequently cause the first isolation valve to close whereupon said performance of said leak test is caused. 2. A process for filling tanks with pressurized gas via a filling station, said process comprising the steps of: providing the filling station of claim 1 ; filling a first vehicle tank with the filling station; after said step of filling the first vehicle tank, filling a second vehicle tank with the filling station; and in between said step of filling of the first vehicle tank and said step of filling of the second vehicle tank, using the electronic data processing and storage member to perform a leak test on the second vehicle tank when a measured pressure of pressurized gas in the circuit trapped between the first and second isolation valves is greater than a predetermined threshold, the second vehicle tank being joined in leaktight fashion to the second end of the circuit, the leak test comprising the steps of: closing the first and second isolation valves, using the electronic data processing and storage member, in order to trap a supply of the pressurized gas in the circuit between the first and second isolation valves; measuring a pressure of the supply of gas trapped in the circuit between the first and second isolation valves; and placing the second tank under pressure via the opening of the second isolation valve at the end of the filling of the first vehicle tank, using the electronic data processing and storage member, wherein, when the measured pressure is lower than the predetermined threshold and before said leak test is performed, the circuit in between the first and second isolation valves is filled with the at least one source of pressurized gas by using the electronic data processing and storage member to open the first isolation valve and when the measured pressure reaches or exceeds the predetermined threshold, the first isolation valve is closed. 3. The process of claim 2 , wherein the predetermined threshold is between 300 bar and 900 bar. 4. The process of claim 2 , wherein the predetermined threshold is between 700 and 860 bar. 5. The process of claim 2 , wherein the predetermined threshold is a pressure value greater than a pressure prevailing in the second tank before the second vehicle tank is filled. 6. The process of claim 2 , wherein the at least one source of pressurized gas comprises at least one pressurized gas storage tank and said step of filling the circuit between the first and second isolation valves is carried out by pressure balancing with the at least one pressurized storage tank. 7. The process of claim 2 , wherein at least between the first and second isolation valves, the circuit comprises one or more thermally insulated pipes. 8. The process of claim 2 , wherein the circuit further comprises, between the first isolation valve and the second isolation valve, a heat exchanger for cooling the pressurized gas being transferred to the first and second vehicle tanks to be filled. 9. The process of claim 8 , wherein the first isolation valve is disposed at a position in the circuit adjacent to the heat exchanger so that the first isolation valve is closer to the heat exchanger than the first isolation valve is to the first end of the circuit. 10. The process of claim 9 , wherein the first isolation valve is located at an inlet of the heat exchanger. 11. The process of claim 8 , wherein the second isolation valve is disposed at a position in the circuit adjacent to the second end of the circuit so that the second isolation valve is closer to the second end of the circuit than the second isolation valve is to the heat exchanger. 12. The process of claim 2 , wherein a volume of the circuit in between the first and second isolation valves is between 0.00005 m 3 and 0.01 m 3 . 13. The process of claim 2 , wherein a length of the circuit between the first and second isolation valves is between one and fifty meters. 14. The process of claim 2 , wherein a length of the circuit between the first and second isolation valves is between two and thirty meters. 15. The process of claim 2 , wherein the pressurized gas is hydrogen. 16. The device of claim 1 , wherein the circuit further comprises a heat exchanger for cooling the pressurized gas transferred to the tank to be filled that is disposed in between the first and second isolation valves.