Patent Number: 
Section: claims

1. A device configured to produce radioisotopes by irradiating a target fluid using a particle beam, the target fluid comprising a radioisotope precursor, the device comprising:an irradiation cell comprising:a conical cavity configured to contain the target fluid, the cavity having an opening at a base of the conical cavity, where the cavity base is surrounded by a front surface of the irradiation cell; anda metal foil connected to the front surface of the irradiation cell and closing the opening of the cavity, wherein the metal foil has a diameter less than or substantially equal to a diameter of the cavity base,wherein an outer surface of the conical cavity comprises furrows extending from an area close to an apex of the conical cavity toward a region close to the base of the cavity, so as to create pathways for the passage of non-cryogenic coolant to flow along the outer surface;a cooling device configured to circulate the non-cryogenic coolant and to cool the walls of the cavity; andan inclined surface, defining the bottom surface of the cavity, so as to evacuate the target fluid, which condenses in contact with the cavity walls, by gravity toward the metal foil;wherein the inclined surface intersects a plane formed by the metal foil at an acute angle (α) with the plane, so as to form, with the metal foil, a corner-shaped area that collects the evacuated target fluid, such that a height of the collected target fluid is maximal at the metal foil and decreases in a direction away from the metal foil. 2. The device according to claim 1, wherein the metal foil is positioned substantially perpendicular to an axis of the particle beam. 3. The device according to claim 1, wherein the radioisotopes are produced by irradiating a target fluid using a substantially horizontal particle beam. 4. The device according to claim 1, wherein a size of the acute angle (α) is between 30° and 89°. 5. The device according to claim 1, wherein the cooling device comprises:a coolant intake situated across from the part of the irradiation cell opposite the foil; anda diffuser creating a channel disposed to circulate the non-cryogenic coolant. 6. The device according to claim 1, wherein an apex of conical cavity is rounded. 7. The device according to claim 1, wherein the irradiation cell comprises:a first part comprising a front surface, which forms a bearing surface for the metal foil, and a rear surface; anda second, substantially conical part, which protrudes relative to the rear surface of the first part;wherein the cavity:passes through the first part to extend into the second part, andforms, in the front surface of the first part, an opening defined by an edge, such that the metal foil closes the opening at the edge when the metal foil bears on the front surface of the first part. 8. The device according to claim 7, wherein the first part further comprises a groove surrounding the second part on a side of the rear surface, the groove being configured to collect the non-cryogenic coolant flowing along an outer surface of the second part. 9. The device according to claim 1, wherein the irradiation cell is made from niobium. 10. An irradiation cell configured to produce radioisotopes by irradiating a target fluid using a particle beam, the target fluid comprising a radioisotope precursor, the irradiation cell comprising:a metal foil;a first part comprising a front surface and a rear surface, the front surface forming a bearing surface for the metal foil;a second, substantially conical part, which protrudes relative to the rear surface of the first part; anda substantially conical cavity, the cavity:having a bottom surface defined by an inclined plane;having an opening at a base of the conical cavity, where the cavity base is surrounded by a front surface of the irradiation cell;being configured to contain the target fluid;passing through the first part to extend into the second part; andrunning into the front surface of the first part at an acute angle (α) to form in the first part the opening defined by an edge,wherein an outer surface of the second part comprises furrows extending from an area close to an apex of the second part toward a region near a base of the second part, so as to create pathways between the furrows for the passage of a non-cryogenic coolant flowing along the outer surface of the second part, andwherein the metal foil is:connected to the front surface of the irradiation cell; andconfigured to close the opening at the edge when the metal foil bears on the front surface of the first part. 11. The irradiation cell according to claim 10, wherein the first part further comprises a groove, which, on a side of the rear surface of the first part, surrounds an outer surface of the second part, so as to reduce a thickness of the first part at the base of the second part, the groove being configured to collect the non-cryogenic coolant flowing along the outer surface of the second part. 12. The device according to claim 1, wherein the acute angle (α) has a size of between 45° and 85°. 13. The device according to claim 1, wherein the acute angle (α) has a size of between 60° and 85°. 14. The device according to claim 1, wherein the cavity comprises an inlet channel disposed proximal to the base of the cavity, the inlet channel being configured to introduce the target fluid into the cavity. 15. The device according to claim 1, wherein the inclined surface comprises an output channel disposed proximal to the base of the cavity, the output channel being configured to remove the collected target fluid. 16. The device according to claim 15, wherein the output channel is angled. 17. The device according to claim 1, wherein the cooling device comprises a diffuser forming an annular channel around the irradiation cell, the annular channel being configured to circulate the non-cryogenic coolant to cool walls of the cavity.