Patent Number: 054065941
Section: claims

1. High rate injection system of cryogenic pellets, comprising at least a pneumatic first and second stage propulsion system, in which high pressure gas in said first stage is supplied against a piston compressing the propelling gas in said second stage through a quick control valve so as to cause in said second stage an almost adiabatic compression of the same propelling gas and to reach at an inlet port of a launching barrel of a pellet downstream of said second stage a high pressure peak up to about 2000 bars for a typical time of the order of ten to hundreds of microseconds. 2. The high rate injection system of cryogenic pellets of claim 1, wherein said second stage and said launching barrel are separated by a vacuum sealing cutoff valve having extremely reduced dead volumes and adapted to stand high pressures and temperatures. 3. The high rate injection system for cryogenic pellets of claim 1, characterized in that the propelling gases and the pellet shot by the launching barrel are fed to decompression chambers connected to a vacuum pump system in series upstream of the user's machine and are provided with dynamic impedances and turbulence chambers to delay the flow of the gases and with cutoff means to entrap the gases after the pellet is shot. 4. The high rate injection system for cryogenic pellets of claim 1, wherein the quick control valve (3) between the first (2) and the second (4) stages includes a cylindrical pressure-containing member or shutter (3a) which is pneumatically pushed into the seat, (3b) by the pressure gas supplied upstream into a chamber (50), the backward movement of said shutter being made extremely quick by a shoulder (56) on which the high pressure in the first stage (2) is acting when chamber (50) is evacuated to the atmosphere. 5. The high rate injection system for cryogenic pellets of claim 2, wherein said cutoff valve is a slide valve (6) formed of a blade (65) sliding into a seat formed in a valve body (61) and provided with a hole (66) for an opening and a closure of a channel (72) connecting said second stage (4) and said launching barrel (7), the movement of said slide valve being controlled by a pneumatic actuator. 6. The high rate injection system for cryogenic pellets of claim 3, wherein said impedances of the decompression chambers (11, 12) are formed of straight pipes (82) which extend within said decompression chambers axially with the cutoff valves, have diameters lower than the width of the decompression chambers but larger than the diameter of the pellet, and are provided at their ends with shaped ports (84) and nozzles (86) forming turbulence chambers. 7. The high rate injection system for cryogenic pellets of claim 3, wherein said decompression chambers have reduced overall dimensions and a capacity of the order of 100-200 liters. 8. The high rate injection system for cryogenic pellets of claim 1, including a drawing pipe for a refrigerating fluid (gas) adapted to draw saturated vapors at constant temperature independently of the level of liquid in a Dewar flask and without mechanical movement within said flask. 9. The high rate injection system for cryogenic pellets of claim 8, wherein said drawing pipe (16) is formed of a pair of concentric pipes, an outer pipe being closed at its end immersed into said Dewar flask, and an inner pipe (16d) within said outer pipe and communicating therewith by an innerspace (16c) between said concentric pipes at ends thereof, holes (16e) for the inlet of vapor into said interspace (16c) being formed in said outer pipe at a level which cannot be reached by the liquid in said Dewar flask. 10. The high rate injection system for cryogenic pellets of claim 1, including one or more cryostats in which the cryogenic pellet is formed by the solidification of small gas volumes in a chamber (90) corresponding to the cold point at the lower end of said launching barrel (7) which is supported by a body (94) adapted to move axially and to rotate with respect to a fixed base (95), in which two seats are formed, a dead seat (97) and a seat (96) connected to the pneumatic propulsion system, the pellet being solidified slowly under a thermal gradient suitably controlled by a heater (100) so as to simulate the typical condition of the growth of single crystals when said launching barrel (7) is located on said dead seat (97), the pellet being launched at the end of the solidification after it is carried to said seat (96). 11. The high rate injection system for cryogenic pellets of claim 1, wherein said at least one pneumatic propulsion system is a multi-stage system. 12. The high rate injection system for cryogenic pellets of claim 1, wherein said launching barrel is more than one. 13. The high rate injection system for cryogenic pellets of claim 2, characterized in that the propelling gases and the pellet shot by the launching barrel are fed to decompression chambers connected to a vacuum pump system in series upstream of the user's machine and are provided with dynamic impedances and turbulence chambers to delay the flow of the gases and with cutoff means to entrap the gases after the pellet is shot. 14. The high rate injection system for cryogenic pellets of claim 2, wherein the quick control valve (3) between the first (2) and the second (4) stages includes a cylindrical pressure-containing member or shutter (3a) which is pneumatically pushed into the seat (3b) by the pressure gas supplied upstream into a chamber (50), the backward movement of said shutter being made extremely quick by a shoulder (56) on which the high pressure in the first stage (2) is acting when chamber (50) is evacuated to the atmosphere. 15. The high rate injection system for cryogenic pellets of claim 3, wherein the quick control valve (3) between the first (2) and the second (4) stages includes a cylindrical pressure-containing member or shutter (3a) which is pneumatically pushed into the seat (3b) by the pressure gas supplied upstream into a chamber (50), the backward movement of said shutter being made extremely quick by a shoulder (56) on which the high pressure in the first stage (2) is acting when chamber (50) is evacuated to the atmosphere. 16. The high rate injection system for cryogenic pellets of claim 3, wherein said cutoff valve is a slide valve (6) formed of a blade (65) sliding into a seat formed in a valve body (61) and provided with a hole (66) for an opening and a closure of a channel (72) connecting said second stage (4) and said launching barrel (7), the movement of said slide valve being controlled by a pneumatic actuator. 17. The high rate injection system for cryogenic pellets of claim 4, wherein said cutoff valve is a slide valve (6) formed of a blade (65) sliding into a seat formed in a valve body (61) and provided with a hole (66) for an opening and a closure of a channel (72) connecting said second stage (4) and said launching barrel (7), the movement of said slide valve being controlled by a pneumatic actuator. 18. The high rate injection system for cryogenic pellets of claim 4, wherein said impedances of the decompression chambers (11, 12) are formed of straight pipe (82) which extend within said decompression chambers axially with the cutoff valves, have diameters lower than the width of the decompression chambers but larger than the diameter of the pellet, and are provided at their ends with shaped ports (84) and nozzles (86) forming turbulence chambers. 19. The high rate injection system for cryogenic pellets of claim 5, wherein said impedances of the decompression chambers (11, 12) are formed of straight pipe (82) which extend within said decompression chambers axially with the cutoff valves, have diameters lower than the width of the decompression chambers but larger than the diameter of the pellet, and are provided at their ends with shaped ports (84) and nozzles (86) forming turbulence chambers. 20. The high rate injection system for cryogenic pellets of claim 4, wherein said decompression chambers have reduced overall dimensions and a capacity of the order of 100-200 liters.