Valve system for an electrochemical power supply source, in particular for an underwater vehicle, and corresponding electrochemical power supply source

1 . An electrochemical-type power supply source ( 1 ), comprising: an electrochemical stack ( 2 ), configured to generate electric power, in the presence, internally, of electrolytic fluid, having a number (n) of distinct groups of galvanic cells ( 4 ) and a corresponding number of electrolyte inlet pipes ( 8 ) for the introduction of electrolyte into the respective groups of galvanic cells ( 4 ) and electrolyte outlet pipes ( 9 ) for the extraction of electrolyte from the respective groups of galvanic cells ( 4 ); a main tank ( 5 ), fluidically coupled to said electrochemical stack ( 2 ) and designed to contain electrolytic fluid; and a recirculation system ( 6 , 10 ), configured to establish a circulation path for circulation of the electrolytic fluid between said main tank ( 5 ) and said electrochemical stack ( 2 ), characterized by comprising a valve system ( 20 ), coupled to said electrolyte inlet pipes ( 8 ) and/or electrolyte outlet pipes ( 9 ) and operatively controllable to jointly modify hydraulic and electrical characteristics of the electrolytic-fluid circulation path, in response to a change of a power delivery condition by said power supply source ( 1 ). 2 . The power supply source according to claim 1 , wherein said valve system ( 20 ), in a low-power delivery condition by said power supply source ( 1 ), is controllable to increase an electrical resistance associated with said circulation path, with respect to a medium/high-power delivery condition by said power supply source ( 1 ). 3 . The power supply source according to claim 1 , further comprising an electronic control unit ( 22 ) configured to reduce a flow rate of said electrolytic fluid in said circulation path in said low-power delivery condition, with respect to the medium/high-power delivery condition by said power supply source ( 1 ). 4 . The power supply source according to claim 2 , wherein said valve system ( 20 ), in said medium/high-power delivery condition by said power supply source ( 1 ), is controllable to reduce the electric resistance of said circulation path, with respect to said low-power delivery condition by said power supply source ( 1 ); and wherein said electronic control unit ( 22 ) is further configured to increase the flow rate of said electrolytic fluid in said circulation path, in said medium/high-power delivery condition, with respect to said low-power delivery condition by said power supply source ( 1 ). 5 . The power supply source according to claim 1 , wherein said valve system ( 20 ) comprises: an inlet valve arrangement ( 24 ), for each electrolyte inlet pipe ( 8 ), coupled to the input of the respective electrolyte inlet pipe ( 8 ); and an outlet valve arrangement ( 25 ), for each electrolyte outlet pipe ( 9 ), coupled to the output of the respective electrolyte outlet pipe ( 9 ). 6 . The power supply source according to claim 5 , wherein said recirculation system ( 6 , 10 ) comprises: a delivery device ( 6 ) coupled to said electrolyte inlet pipes ( 8 ) for introducing said electrolytic fluid into said electrochemical stack ( 2 ); and a conditioning device ( 10 ) coupled to said electrolyte outlet pipes ( 9 ) for conditioning operations of the electrolytic fluid extracted from said electrochemical stack ( 2 ), wherein each inlet valve arrangement ( 24 ) is coupled to the input of the respective electrolyte inlet pipe ( 8 ), downstream of the delivery device ( 6 ); and each outlet valve arrangement ( 25 ) is coupled to the output of the respective electrolyte outlet pipe ( 9 ), upstream of the conditioning device ( 10 ). 7 . The power supply source according to claim 5 , wherein each inlet valve arrangement ( 24 ) and each outlet valve arrangement ( 25 ) defines a respective inlet (IN) and a respective outlet (OUT) for the electrolytic fluid and comprises: a direct fluidic path ( 26 ), which fluidically connects the respective inlet (IN) and the respective outlet (OUT) through a path with a high section and low length, i.e. with a low length/section ratio; a secondary fluidic path ( 27 ), which fluidically connects the respective inlet (IN) and the respective outlet (OUT) by means of a path with a low section and high length, i.e. with a high length/section ratio; a valve device ( 28 ), operable in a first position in which it closes, alternatively in a second position in which it opens, said direct fluidic path ( 26 ) between said inlet (IN) and said outlet (OUT), wherein said secondary fluidic path ( 27 ) is traversed by said electrolytic fluid, in the closing position of said direct fluidic path ( 26 ) by said valve device ( 28 ). 8 . The power supply source according to claim 7 , further comprising an electronic control unit ( 22 ) configured to control the valve device ( 28 ) of the inlet and outlet valve arrangements ( 24 , 25 ) of said valve system ( 20 ), as a function of the power delivery condition; wherein, in a low-power delivery condition by said power supply source ( 1 ), the electronic control unit ( 22 ) controls the valve device ( 28 ) in said first position, so that the flow of the electrolytic fluid between the inlet (IN) and the outlet (OUT) of the respective inlet ( 24 ) and/or outlet ( 25 ) valve arrangement takes place through the secondary fluidic path ( 27 ), having a high length/section ratio, so as to increase the electrical resistance, at the same time increasing the hydraulic pressure loss; and wherein, in a medium/high-power delivery condition by the power supply source ( 1 ), the electronic control unit ( 22 ) controls the valve device ( 28 ) in the second position, so that the flow of the electrolytic fluid between the inlet (IN) and the outlet (OUT) of the respective inlet ( 24 ) and/or outlet ( 25 ) valve arrangement occurs through the direct fluidic path ( 26 ), having a high section and low length, so as to reduce the electrical resistance, at the same time reducing the hydraulic pressure loss. 9 . The power supply source according to claim 8 , wherein said electronic control unit ( 22 ) is configured to provide the command for switching from the first position to the second position simultaneously on all the inlet and outlet valve arrangements ( 24 , 25 ), upon switching from the low-power delivery condition to the medium/high-power delivery condition by said power supply source ( 1 ). 10 . The power supply source according to claim 7 , wherein each inlet and outlet valve arrangement ( 24 , 25 ) comprises a main body ( 30 ) having a longitudinal extension, an outer wall ( 31 ) and, internally, to said outer wall ( 31 ), a fluidic duct which defines said primary fluidic path ( 26 ); wherein, in said outer wall ( 31 ) a coiled duct is formed which defines said secondary fluidic path ( 27 ); and wherein said valve device ( 28 ) comprises a shutter ( 32 ) arranged centrally with respect to the main body ( 30 ) and having a cavity ( 33 ) coaxial with said primary fluidic path ( 26 ), controllable in rotation by an actuator ( 34 ) between a first position, in which it closes said primary fluidic path ( 26 ), forcing the electrolytic fluid to flow along said secondary fluidic path ( 27 ), and a second position, in which it opens said primary fluidic path ( 26 ), which is then traversed by the electrolytic fluid. 11 . The power supply source according to claim 6 , further comprising a second tank ( 48 ), configured to contain electrolytic fluid at a temperature lower than the temperature of the electrolytic fluid in the main tank ( 5 ); wherein said conditioning device ( 10 ) comprises at least one of the following: a heat exchanger ( 42 ) which fluidically connects said main tank ( 5 ) and said second tank ( 48 ), cooling electrolytic fluid drawn from sa