Cryogenic fluid storage tank

What is claimed is: 1. A tank for storing a two-phase mixture of liquid and of gaseous cryogenic fluid, comprising: a first casing intended to contain the cryogenic fluid; a vaporized gas drawing-off pipe comprising a first upstream end connected to the upper part of the first casing in order to draw-off fluid in the gaseous state, said vaporized gas drawing-off pipe comprising a vaporizer and at least one regulating valve toward a downstream distribution end; a circuit for filling the tank; a pipe for pressurizing the first casing comprising a first end connected to the lower end of the first casing and a second end connected to the upper part of the first casing, the pressurization pipe comprising at least one regulating valve and a heater, the heater being a vaporization heat exchanger; and an air venting regulator connected to the upper end of the first casing, wherein: the circuit comprises a first filling pipe having an upstream end intended to be connected to a fluid source and a downstream end connected to the lower portion of the first casing, a second filling pipe having an upstream end intended to be connected to the fluid source and a downstream end connected to the upper portion of the first casing, and a set of one or more distribution valve(s) configured to allow distribution of the fluid originating from the fluid source in the first and second filling pipes; and the set of one or more distribution valve(s) of the filling circuit, the regulating valve of the pressurization pipe, the regulating valve of the drawing-off circuit and the air venting regulator are integrated in a same module of one or more valve(s) sharing at least one valve element. 2. The tank of claim 1 , wherein the module comprises a first orifice intended to be connected to a fluid source for filling the tank, a second orifice connected to the downstream end of the first filling pipe, a third orifice connected to the vaporized gas drawing-off pipe, a fourth orifice connected to a gas discharging zone, a fifth orifice connected to the second end of the pressurization pipe, a sixth orifice connected to the second end of the pressurization pipe of the first casing, and at least one movable element allowing the circulation of fluid through the orifices to be controlled. 3. The tank of claim 2 , wherein at least one movable element allows connection or non-connection between at least of two of said orifices. 4. The tank of claim 2 , wherein the fourth orifice is connected to the atmosphere. 5. The tank of claim 1 , wherein: the tank comprises a set of one or more sensor(s) measuring a pressure in the first casing and optionally also a pressure in the filling circuit; the module is sensitive to the pressure measured by the set of one or more sensor(s) and is configured to automatically control, as a function of the pressure measured by the set of one or more sensor(s), the flows of fluid via one or more of: the set of one or more distribution valve(s) of the filling circuit, the regulating valve of the pressurization pipe, the regulating valve of the drawing-off circuit, and the air venting regulator. 6. The tank of claim 5 , wherein the at least one movable element of the module of one or more valve(s) is sensitive to the pressure measured by the set of one or more sensor(s) and is configured to automatically control the fluid connection or non-connection between at least two orifices as a function of the pressure measured by the set of one or more sensor(s). 7. The tank of claim 6 , wherein: the set of one or more sensor(s) comprises a sensor for detecting a pressure or a mechanical connection at the first orifice; and when said sensor for detecting a pressure or a mechanical connection at the first orifice detects a pressure or a mechanical connection that is higher than a determined high threshold, the at least one movable element of the module is configured to switch to a “filling mode” in which the third orifice and the fourth orifice are closed and the first orifice is fluidly connected to the second orifice and/or to the sixth orifice. 8. The tank of claim 7 , wherein: in the filling mode, the at least one movable element of the module of one or more valve(s) is configured to automatically regulate the pressure in the first casing to a predetermined pressure setpoint (Pc) during filling by ensuring automatic distribution of the flow of fluid originating from the source in the first and second filling pipes as a function of the pressure setpoint Pc and of the pressure measured by the set of one or more sensor(s); and distribution of the flow in said first and second pipes is implemented by connecting the first orifice to the second orifice and/or to the sixth orifice. 9. The tank of claim 7 , wherein, when said sensor for detecting a pressure or a mechanical connection at the first orifice detects a pressure or a mechanical connection lower than a determined low threshold, the at least one movable element of the module of one or more valve(s) is configured to switch to a non-filling mode in which the first orifice is closed. 10. The tank of claim 9 , wherein, in the non-filling mode, the at least one movable element of the module of one or more valve(s) is configured to automatically maintain the pressure in the first casing at a minimum determined pressure value by ensuring, when the pressure in the first casing is lower than said minimum value, that liquid taken from the first casing is circulated in the heater and then re-introduced into the first casing via a flow of fluid between the second orifice and the fifth orifice. 11. The tank of claim 9 , wherein, in the non-filling mode, the at least one movable element of the module of one or more valve(s) is configured to automatically reduce, during drawing-off via said drawing-off pipe, the pressure in the first casing below a first maximum value by ensuring, when the pressure in the first casing is higher than said first maximum value, that gas taken from the first casing is circulated toward the downstream distribution end of the gas drawing-off pipe via a flow of fluid between the fifth orifice and the third orifice. 12. The tank of claim 2 , wherein the at least one movable element of the module of one or more valve(s) comprises a sector or distributor that is translationally and/or rotationally movable. 13. The tank of claim 12 , wherein: the at least one movable element is translationally or rotationally movable between a distinct first position and a distinct second position respectively corresponding to the “filling” and “non-filling” modes; and in each of the first and second positions, said at least one movable element of the module of one or more valve(s) is rotationally and/or translationally movable in order to control the fluid connection or non-connection between at least two of the orifices. 14. The tank of claim 9 , wherein, in the non-filling mode, the at least one movable element of the module of one or more valve(s) is configured to automatically reduce the pressure in the first casing below a second maximum value by ensuring, when the pressure in the first casing is higher than said second maximum value, that gas taken from the first casing at the end is circulated toward the fourth orifice via the fifth orifice, in order to ensure that said gas is discharged, for example, by venting. 15. The tank of claim 14 , wherein, in the non-filling mode, the at least one movable element of the module of one or more valve(s) is configured to automatically reduce the pressure in the first casing below a second maximum value by ensuring, when the pressure in th