Hydrothermal oxidation device for treating a material in a supercritical medium and implementation method

The invention claimed is: 1. An hydrothermal oxidation device for treatment of a material in a supercritical medium, comprising: a main body comprising a cold interface flange at a first of its ends, sealing means between the main body and the flange, the main body, the flange and the sealing means being made from materials resistant to pressures and temperatures in supercritical media; an internal tube placed inside the main body to form an annular zone along the main body, the internal tube comprising a cold first end and a hot second end, the first end of the internal tube being fixed in a sealed manner to the cold interface flange, the internal tube delimiting an internal reaction zone; a stirring means placed in the internal reaction zone of the internal tube and actuated by a rotating shaft; a cooling means to cool a treated material located in the internal reaction zone of the internal tube before it is evacuated from the oxidation device through a treated material outlet; an inlet for a water and oxidant mix located at the cold first end of the main body, the water and oxidant mix passing through the annular zone from the cold first end to the hot second end of the internal tube, before penetrating into the internal reaction zone of the internal tube; an effluents outlet located at the cold first end of the main body; an inlet for material to be treated, located at a hot second end of the main body, this inlet opening up into the internal tube, at its second end; and an inlet for a diluted effluent, located in the cold interface flange and connected to a preheating coil located along an internal wall of the main body and extending from its cold first end to its hot second end, the preheating coil opening up into the reaction zone of the internal tube at its hot second end. 2. The hydrothermal oxidation device according to claim 1 , further comprising a heat exchanger forming a hot loop heat sink located in the annular zone and in a peripheral zone located adjacent to the hot second end of the internal tube, the hot loop heat sink drawing off heat from an hydrothermal oxidation reaction that occurs in the second end of the internal zone of the internal tube. 3. The hydrothermal oxidation device according to claim 1 , further comprising a reaction antechamber located on a same side as the hot second end of the internal tube, the reaction antechamber being formed by an internal wall and an external wall closing off the internal tube, a communication passage for the mix of water and oxidant being formed in each of the internal and external walls. 4. The hydrothermal oxidation device according to claim 3 , further comprising an electrical heating means located in the main body and opening up in the annular zone, close to the reaction antechamber, the heating means being protected by this arrangement from chemical aggression induced by the waste or the hydrothermal oxidation reaction. 5. The hydrothermal oxidation device according to claim 1 , further comprising a heat exchanger forming a cold loop heat sink that lowers a temperature of a fluid medium after the reaction to realize conditions for a resistance of sealing devices of the main body on the flanges and to optimize solubilization of precipitated mineral species. 6. The hydrothermal oxidation device according to claim 1 , further comprising a solids management module including a lid that closes off a through orifice formed in the flange, cold sealing means being provided between the solids management module and the flange. 7. The hydrothermal oxidation device according to claim 6 , further comprising a solids treatment rotor driven in rotation by a magnetic drive, the solids treatment rotor having a circular shaped axial section and being adjusted to have a clearance in a corresponding diameter of the solids management module, the solids treatment rotor making it possible to perform a mechanical treatment of solids present in the cooled effluent output from a hydrothermal reaction and bringing these solids to a sufficiently small size grading so that pipes and equipment located downstream from the solids management module are not clogged. 8. A method for continuous treatment of a material by hydrothermal oxidation, comprising: a) introducing fluid comprising water and an oxidant into a reactor at a pressure of more than 22.1 MPa, in an annular zone formed between an internal wall of a main body of a reactor and an internal tube in the main body, at a cold first end of the main body; b) heating the water/oxidant fluid in the annular zone to a temperature of more than 374° C.; c) introducing the heated water/oxidant fluid under pressure obtained in b) into the internal tube of the reactor at a hot second end of the main body, and simultaneous introduction of the material to be treated into the internal tube at the hot second end of the main body; d) mixing the heated water/oxidant fluid under pressure and the material to be treated in a first part of the internal tube to oxidize the material to be treated and cooling of the fluid/oxidized material mix thus obtained in a second part of the internal tube; e) evacuating the fluid/oxidized material mix from the reactor at a cold first end of the main body; and f) adding a diluted effluent into a preheating coil, the inlet of the coil being located at the cold first end of the main body, the coil being wound along the internal wall of the main body and opening up in the first part of the internal tube. 9. The method according to claim 8 , further comprising g) cooling a reaction zone located inside the internal tube at a hot second end of this internal tube by a heat exchanger forming a hot loop heat sink arranged in contact with the internal tube. 10. The method according to claim 8 , wherein the water/oxidant fluid in the annular zone between the internal wall of the main body and the external wall of the internal tube is heated using: one or plural electrical resistances located immediately adjacent to the reaction antechamber; the hot loop heat sink; and heat produced by the hydrothermal reaction. 11. The method according to claim 8 , wherein heat is extracted from the internal tube close to its first cold end by a heat exchanger forming a cold loop heat sink, the heat exchanger lowering temperature of the fluid medium after the hydrothermal reaction and before it exits from the reactor. 12. The method according to claim 8 , wherein solids present in the cooled effluent are treated mechanically by grinding them between an internal wall of a solids management module connected to a flange of the reactor and an external wall of a solids treatment rotor to obtain a sufficiently fine size grading chosen to not clog up pipes and equipment downstream from the solids management module.