초록 ▼

A method for filling a gas tank at a pressure P2 from at least one gas source at a pressure Pi, P1 being higher than V2, said container and said at least one gas source being connected by a duct allowing the passage of gas from one to the other, the filing being carried out at a flow rate which is,

A method for filling a gas tank at a pressure P2 from at least one gas source at a pressure Pi, P1 being higher than V2, said container and said at least one gas source being connected by a duct allowing the passage of gas from one to the other, the filing being carried out at a flow rate which is, at the end of the filling, lower than the initial flow rate, wherein said method comprises several successive filling steps 1 to i, each of the steps being carried out with a filling flow rate D1 to Di for a time t1 to ti, i being an integer higher than or equal to 2, the flow rate of a step i-1 being higher than the flow rate of the step i,; characterized in that the successive filling steps 1 to i are adapted for producing a controlled heating of the container that maximizes the heat dispersal in said container without increasing the temperature inside the container beyond the maximum accepted temperature for the container, and in that the sum of ti is between 1 and 7 minutes, preferably between 1 min 30 sec and 5 minutes, and more preferably between 2 and 4 minutes.

대표청구항 ▼

1. A method of filling a container with gas to a pressure P2 from at least one gas source at a pressure P1, P1 being greater than P2, said container and said at least one gas source being connected via a line enabling the gas to pass from one to the other, the filling taking place at a flow rate whi

1. A method of filling a container with gas to a pressure P2 from at least one gas source at a pressure P1, P1 being greater than P2, said container and said at least one gas source being connected via a line enabling the gas to pass from one to the other, the filling taking place at a flow rate which, at the end of filling, is lower than the initial flow rate, the method comprising several successive filling steps 1 to i, each of the steps being carried out with a filling flow rate D1 to Di for a time t1 to ti, i being an integer equal to or greater than 2, the flow rate of step i-1 being higher than the flow rate of step i, characterized in that the successive filling steps 1 to i are designed in terms of flow rate and duration so as to produce controlled heating of the container thereby maximizing the heat dissipation in said container without correspondingly increasing the temperature inside the container above the maximum temperature tolerated by the tank, the filling flow rate being adjusted according to the measured or estimated temperature of the container and the sum of the tis being between 1 and 7 minutes. 2. The filling method of claim 1, wherein i is an integer from 2 to 20. 3. The filling method of claim 1, wherein it comprises three successive filling steps, the first filling step of which with a flow rate D1 for a time t1, the second filling step with a flow rate D2 for a time t2 and the third filling step with a flow rate D3 for a time t3, where D1>D2>D3, the sum of the times t1+t2+t3 being between 1 and 7 minutes. 4. The filling method of claim 1, wherein the successive filling steps are carried out with successive decreasing flow rates, each having a different rate of decrease. 5. The filling method of claim 1, wherein the gas source and/or the container and/or the line enabling the gas to pass from one to the other are/is cooled. 6. The filling method of claim 1, wherein the rate at which said container is filled is regulated using an on/off valve placed on said line enabling the gas to pass. 7. The filling method of claim 1, wherein the rate at which said container is filled is regulated using a variable-flow regulating valve placed on said line enabling the gas to pass. 8. The filling method of claim 7, wherein the variable-flow regulating valve is controlled using a PID (proportional, integral, derivative) regulator of constant or variable action. 9. The filling method of claim 7, wherein the variable-flow regulating valve is controlled using a regulator with predictive action. 10. The filling method of claim 1, wherein the rate at which said container is filled is regulated using a set of on/off valves having different flow cross sections placed in parallel on said line enabling the gas to pass. 11. The filling method of claim 1, wherein the rate at which said container is filled is regulated using the variation in the frequency of the electrical supply for a compressor or using the variation in the frequency of the pneumatic supply for a compressor. 12. The method of claim 1, wherein the first of the successive filling steps is designed so as to achieve, without exceeding it, a gas temperature inside the container equal to the maximum value tolerated by the container. 13. The method of claim 12, wherein the filling steps after the first step are designed to keep the gas temperature inside the container equal to the maximum value tolerated by the container. 14. The method of claim 1, wherein it includes a step of calculating an optimum filling rate curve as a function of time, said optimum curve being calculated beforehand in order to obtain a minimized total filling time, as a function of: the geometry and/or thermal resistance characteristics of the tank; the ambient temperature; the pressure and temperature of the source gas; the maximum permissible wall temperature of the tank, and the maximum fill rate possible. 15. The filling method of claim 1, wherein: said method includes a step of calculating an optimum filling rate curve as a function of time;said optimum curve being calculated beforehand in order to obtain a minimized total filling time;the optimum filling curve lying between two limit curves, the lower limit and the upper limit respectively, which are calculated and correspond to percentage of a total mass of the gas to be transferred relative to a percentage of the total filling time;the lower limit curve calls for: 12% of the total mass to be transferred at 10% of the total filing time, 25% of the total mass to be transferred at 20% of the total filing time, 37.5% of the total mass to be transferred at 30% of the total filing time, 48% of the total mass to be transferred at 40% of the total filing time, 58% of the total mass to be transferred at 50% of the total filing time, 68% of the total mass to be transferred at 60% of the total filing time, 75% of the total mass to be transferred at 70% of the total filing time, 82.5% of the total mass to be transferred at 80% of the total filing time, 91% of the total mass to be transferred at 90% of the total filing time, and 100% of the total mass to be transferred at 100% of the total filing time; andthe upper limit curve calls for: 35% of the total mass to be transferred at 10% of the total filing time, 48% of the total mass to be transferred at 20% of the total filing time, 58% of the total mass to be transferred at 30% of the total filing time, 67% of the total mass to be transferred at 40% of the total filing time, 75% of the total mass to be transferred at 50% of the total filing time, 83% of the total mass to be transferred at 60% of the total filing time, 88% of the total mass to be transferred at 70% of the total filing time, 92% of the total mass to be transferred at 80% of the total filing time, 96% of the total mass to be transferred at 90% of the total filing time, and 100% of the total mass to be transferred at 100% of the total filing time. 16. The filling method of claim 1, wherein the sum of the tis is between between 1 minute 30 seconds and 5 minutes. 17. The filling method of claim 1, wherein the sum of the tis is between between 2 and 4 minutes. 18. The filling method of claim 1, wherein i is an integer from 2 to 5.