Stator-rotor vortex chamber for mass and/or heat transfer processes

The invention claimed is: 1. A device for bringing a solid-phase or liquid target medium into contact with a carrier fluid in a process that requires intensive interfacial momentum, mass and/or energy exchange between the carrier fluid and the target medium, the device comprising: a chamber comprising a circumferential wall, a bottom wall and a top wall, said chamber forming an enclosure for said target medium while contacting said carrier fluid in operation of said device, said chamber being substantially rotationally symmetric with respect to an axis of symmetry, said chamber being adapted for remaining mechanically static in operation of said device; at least one fluid inlet adapted for injecting said carrier fluid under pressure into said chamber, wherein an injection direction of the carrier fluid is substantially tangential to an inner surface of said circumferential wall; an outlet for letting the carrier fluid flow out of the chamber, and a fluid distributor arranged in said chamber and comprising a perforated cylindrical wall, said fluid distributor being adapted for diverting said injected carrier fluid to pass through said perforated cylindrical wall in a substantially radial inward direction with respect to said axis of symmetry, said fluid distributor being substantially rotationally symmetric with respect to said axis of symmetry and adapted for rotating around said axis of symmetry, a contact region between the target medium and the carrier fluid being delimited by and extending from the perforated cylindrical wall in said radial inward direction, a rotatable shaft for rotating around said axis of symmetry, said rotatable shaft being mechanically linked to said fluid distributor to rotatably mount said fluid distributor in said chamber, wherein said fluid distributor comprises at least one fin extending from said fluid distributor in a substantially radial outward direction with respect to said axis of symmetry, the at least one fin being arranged for converting kinetic energy of the injected carrier fluid into rotational energy of the fluid distributor while redirecting the injected carrier fluid to pass in said substantially radial inward direction through perforations of said perforated cylindrical wall, wherein at least a part of said bottom wall of the chamber is formed by a bottom plate that is arranged centrally around said axis of symmetry in a plane perpendicular to said axis of symmetry and that is mechanically decoupled from said fluid distributor such as to remain mechanically static when said fluid distributor rotates around said axis of symmetry, and wherein said fluid distributor further comprises a linkage structure for mechanically linking said rotatable shaft to said fluid distributor, said linkage structure comprising a plate that is oriented perpendicular to said shaft, said plate being grooved such as to form a labyrinth fluid seal in conjunction with said bottom plate. 2. The device of claim 1 , said device being adapted for forming a rotating bed of said target medium and said carrier fluid upon rotation of said fluid distributor about said axis of symmetry, wherein said rotating bed forms on an inner surface of the cylindrical wall. 3. The device of claim 1 , wherein said at least one fin is curved, having a free end portion distal from said fluid distributor and angularly shifted with respect to a fixed end portion proximal to said fluid distributor, said angular shift being an angular shift around said axis of symmetry against the direction of flow in which said carrier fluid is injected into said chamber by said at least one fluid inlet in operation of said device. 4. The device of claim 1 , wherein said at least one fin comprises at least three fins uniformly distributed around a circumference of said fluid distributor. 5. The device of claim 1 , wherein the bottom plate is arranged inside the fluid distributor and a gap is formed in a radial direction between an outer diameter of the bottom plate and a lower base portion of the fluid distributor. 6. The device of claim 1 , wherein said bottom plate is rotationally symmetric with respect to said axis of symmetry and is tapered such as to extend toward the top wall in a central region of said bottom plate and away from said top wall in a peripheral region of said bottom plate. 7. The device of claim 1 , wherein said rotatable shaft comprises an external bearing at its outer surface, configured to engage a corresponding cuff formed in a housing of said chamber. 8. The device of claim 1 , wherein said rotatable shaft is a hollow shaft, wherein said rotatable shaft comprises an internal bearing at its inner surface, configured to engage a spindle that is coaxially provided inside said rotatable shaft, said spindle being mechanically linked to said bottom plate. 9. The device of claim 1 , wherein said at least one fluid inlet comprises a nozzle formed in said circumferential wall, said nozzle having a first wall section that connects continuously and tangentially to said inner surface of said circumferential wall and a second wall section that connects to said inner surface of said circumferential wall at an acute angle such as to focus a flow of said injected carrier fluid azimuthally along said inner surface of said circumferential wall. 10. The device of claim 1 , wherein the chamber is a cylindrical chamber with a height-to-diameter ratio of at most five. 11. The device of claim 1 , wherein the perforations of the perforated cylindrical wall form an H-shaped slit pattern. 12. A system comprising the device of claim 1 and a pressure regulator connectable to a supply of pressurized carrier fluid, the pressure regulator being capable of regulating a mass flow of the carrier fluid through the at least one fluid inlet at a rate sufficient to cause a rotary motion of the fluid distributor. 13. A method for bringing a target medium into contact with a carrier fluid in a process that requires intensive interfacial momentum, mass and/or energy exchange between the carrier fluid and the target medium, the method comprising: feeding said target medium into a chamber adapted for containing said target medium while contacting said carrier fluid, said chamber being substantially rotationally symmetric with respect to an axis of symmetry and adapted for remaining mechanically static while performing said method; injecting said carrier fluid under pressure into said chamber, said injecting being substantially tangential to an inner surface of a circumferential wall of said chamber; passing the injected carrier fluid in a substantially radial inward direction through a perforated cylindrical wall of a fluid distributor rotatably mounted in said chamber; letting said carrier fluid flow out of said chamber; preventing leakage of the carrier fluid from the chamber by disposing a fluid labyrinth seal between a bottom plate of the chamber and a grooved plate of a linkage structure for mechanically linking a rotatable shaft to said fluid distributor, said bottom plate being arranged centrally around said axis of symmetry in a plane perpendicular to said axis of symmetry and mechanically decoupled from said fluid distributor such as to remain mechanically static when said fluid distributor rotates around said axis of symmetry, and said grooved plate being oriented perpendicular to said shaft; feeding the target medium into a contact region delimited by and extending from the perforated cylindrical wall in said radial inward direction; and deflecting the injected carrier fluid on at least one fin extending from said fluid distributor in a substantially radial outward direction, thereby