초록 ▼

Disclosed herein is an iodine-sulfur cycle for nuclear hydrogen production, which can improve thermochemical efficiency. The iodine-sulfur cycle is advantageous in that the amount of excess water and iodine supplied to a Bunsen reaction process is minimized, thus minimizing the amount of thermal ene

Disclosed herein is an iodine-sulfur cycle for nuclear hydrogen production, which can improve thermochemical efficiency. The iodine-sulfur cycle is advantageous in that the amount of excess water and iodine supplied to a Bunsen reaction process is minimized, thus minimizing the amount of thermal energy consumed in the recovery and recirculation process thereof, in that sulfuric acid having stronger hydrophilicity than hydrogen iodide absorbs excess water in large quantities in a spontaneous liquid-liquid phase separation process, so that, after the spontaneous liquid-liquid phase separation process, the concentration of hydrogen iodide in a hydrogen iodide solution exceeds a concentration at an azeotropic point without conducting an additional concentration process, with the result that highly-concentrated hydrogen iodide gas can be obtained only through a flashing process, thereby decreasing energy consumption and simplifying the process and thus improving economical efficiency, and in that process temperature and pressure can be decreased, thus greatly deceasing the corrosivity in an operational environment. Therefore, the iodine-sulfur cycle according to the present invention can be usefully used for high-efficient and environmentally-friendly nuclear hydrogen production.

대표청구항 ▼

1. An iodine-sulfur cycle for nuclear hydrogen production, comprising: a Bunsen reaction process including a liquid-liquid phase separation process;a hydrogen iodide decomposition process; anda sulfuric acid decomposition process,wherein sulfur dioxide, iodine, and water, which are reactants necessa

1. An iodine-sulfur cycle for nuclear hydrogen production, comprising: a Bunsen reaction process including a liquid-liquid phase separation process;a hydrogen iodide decomposition process; anda sulfuric acid decomposition process,wherein sulfur dioxide, iodine, and water, which are reactants necessarily used to conduct the Bunsen reaction process, mix with excess water and excess iodine and then react with each other at an operating temperature of 330˜350K (57˜77° C.) as represented by the following Reaction Formula 1: (5˜7).I2+SO2+(13˜15).H2O[2HI+4.I2+(6˜8).H2O]+[H2SO4+5.H2O],  wherein concentration of hydrogen iodide in the hydrogen iodide solution produced and separated by the Bunsen reaction process conducted as the reaction Formula 1 exceeds a concentration at an azeotropic point; andwherein the cycle further comprising a flashing process of separating hydrogen iodide from the hydrogen iodide solution. 2. The iodine-sulfur cycle for nuclear hydrogen production according to claim 1, wherein the Bunsen reaction process has an optimal operating point at a temperature of 330K as represented by the following Reaction Formula 2: 5.I2+SO2+13.H2O[2HI+4.I2+6.H2O]+[H2SO4+5.H2O]  . 3. The iodine-sulfur cycle for nuclear hydrogen production according to claim 1, wherein, in the Bunsen reaction process conducted as represented by the Reaction Formula 1, an amount of excess water and iodine introduced into a spontaneous liquid-liquid phase separation process for a sulfuric acid solution and a hydrogen iodide solution is optimized, thus increasing efficiency of the entire iodine-sulfur cycle. 4. The iodine-sulfur cycle for nuclear hydrogen production according to claim 1, further comprising: a flashing process of separating hydrogen iodide from the hydrogen iodide solution; anda recirculation process of recirculating a residual hydrogen iodide solution having a material balance represented by the following Reaction Formula 3 to the Bunsen reaction process, Residual hydrogen iodide solution: (3˜4)HI+(10˜15).I2+(15˜20).H2O  . 5. The iodine-sulfur cycle for nuclear hydrogen production according to claim 4, wherein the recirculating residual hydrogen iodide solution is mixed with reactants before the Bunsen reaction process of claim 1, and then a Bunsen reaction process represented by the following Reaction Formula 4 is conducted using the mixture to produce a liquid-liquid phase separated hydrogen iodide solution having a material balance represented by the following Reaction Formula 5: Bunsen reaction process: (3˜4)HI+[2+(20˜25)].H2O+[1+(10˜15)].I2+SO2H2SO4+[2+(3˜4)].HI+(10˜15).I2+(20˜25).H2O  Liquid-liquid phase separated hydrogen iodide solution: [2+(3˜4)].HI+(10˜15).I2+(15˜20).H2O  . 6. The iodine-sulfur cycle for nuclear hydrogen production according to claim 5, wherein the Reaction Formulae 3 to 5 have optimal operating points represented by the following Reaction Formulae 6 to 8, respectively: Residual hydrogen iodide solution: 3HI+10.I2+15.H2O  Bunsen reaction process: 3HI+(2+20).H2O+(1+10).I2+SO2H2SO4+(2+3).HI+10.I2+20.H2O  Liquid-liquid phase separated hydrogen iodide solution: (2+3).HI+10.I2+15.H2O  . 7. The iodine-sulfur cycle for nuclear hydrogen production according to claim 4, wherein the residual hydrogen iodide solution represented by the Reaction Formula 1 is mixed with the reaction product after the Bunsen reaction process of claim 1 to form a mixed solution represented by the following Reaction Formula 9, and then the mixed solution is separated into a hydrogen iodide solution represented by the following Reaction Formula 10 through a liquid-liquid phase separation process: Mixed solution: H2SO4+[2+(3˜4)].HI+(10˜15)I2+(20˜25).H2O  Hydrogen iodide solution after liquid-liquid phase separation: [2+(3˜4)].HI+(10˜15).I2+(15˜20).H2O  . 8. The iodine-sulfur cycle for nuclear hydrogen production according to claim 7, wherein the Reaction Formulae Reaction Formulae 3, 9 and 10 have optimal operating points represented by the Reaction Formula 6 of claim 7 and the following Reaction Formulae 11 and 12, respectively: Mixed solution: H2SO4+[2+3].HI+10.I2+20.H2O  Liquid-liquid phase separated hydrogen iodide solution: (2+3).HI+10.I2+15.H2O  . 9. The iodine-sulfur cycle for nuclear hydrogen production according to claim 4, wherein concentration of hydrogen iodide in the residual hydrogen iodide solution is a concentration at the pseudo-azeotropic point. 10. An iodine-sulfur cycle for nuclear hydrogen production, comprising: a Bunsen reaction process including a liquid-liquid phase separation process;a hydrogen iodide decomposition process; anda sulfuric acid decomposition process,wherein sulfur dioxide, iodine, and water, which are reactants necessarily used to conduct the Bunsen reaction process, mix with excess water and excess iodine and then react with each other at an operating temperature of 330˜350K (57˜77° C.) as represented by the following Reaction Formula 1: (5˜7).I2+SO2+(13˜15).H2O[2HI+4.I2+(6˜8).H2O]+[H2SO4+5.H2O];  wherein concentration of hydrogen iodide in the hydrogen iodide solution produced and separated by the Bunsen reaction process conducted as the reaction Formula 1 exceeds a concentration at an azeotropic point;wherein the cycle further comprising a flashing process of separating hydrogen iodide from the hydrogen iodide solution, andwherein SO2 from the sulfuric acid decomposition process is recycled to the Bunsen reaction. 11. The iodine-sulfur cycle for nuclear hydrogen production according to claim 10, wherein the Bunsen reaction process has an optimal operating point at a temperature of 330K as represented by the following Reaction Formula 2: 5.I2+SO2+13.H2O[2HI+4.I2+6.H2O]+[H2SO4+5.H2O]  . 12. The iodine-sulfur cycle for nuclear hydrogen production according to claim 10, wherein, in the Bunsen reaction process conducted as represented by the Reaction Formula 1, an amount of excess water and iodine introduced into a spontaneous liquid-liquid phase separation process for a sulfuric acid solution and a hydrogen iodide solution is optimized, thus increasing efficiency of the entire iodine-sulfur cycle. 13. The iodine-sulfur cycle for nuclear hydrogen production according to claim 10, further comprising: a flashing process of separating hydrogen iodide from the hydrogen iodide solution; anda recirculation process of recirculating a residual hydrogen iodide solution having a material balance represented by the following Reaction Formula 3 to the Bunsen reaction process: Residual hydrogen iodide solution: (3˜4)HI+(10˜15).I2+(15˜20).H2O  . 14. The iodine-sulfur cycle for nuclear hydrogen production according to claim 13, wherein the recirculating residual hydrogen iodide solution is mixed with reactants before the Bunsen reaction process of claim 11, and then a Bunsen reaction process represented by the following Reaction Formula 4 is conducted using the mixture to produce a liquid-liquid phase separated hydrogen iodide solution having a material balance represented by the following Reaction Formula 5: Bunsen reaction process: (3˜4)HI+[2+(20˜25)].H2O+[1+(10˜15)].I2+SO2H2SO4+[2+(3˜4)].HI+(10˜15).I2+(20˜25).H2O  Liquid-liquid phase separated hydrogen iodide solution: [2+(3˜4)].HI+(10˜15).I2+(15˜20).H2O  . 15. The iodine-sulfur cycle for nuclear hydrogen production according to claim 14, wherein the Reaction Formulae 3 to 5 have optimal operating points represented by the following Reaction Formulae 6 to 8, respectively: Residual hydrogen iodide solution: 3HI+10.I2+15.H2O  Bunsen reaction process: 3HI+(2+20).H2O+(1+10).I2+SO2H2SO4+(2+3).HI+10.I2+20.H2O  Liquid-liquid phase separated hydrogen iodide solution: (2+3).HI+10.I2+15.H2O  . 16. The iodine-sulfur cycle for nuclear hydrogen production according to claim 13, wherein the residual hydrogen iodide solution represented by the Reaction Formula 1 is mixed with the reaction product after the Bunsen reaction process of claim 11 to form a mixed solution represented by the following Reaction Formula 9, and then the mixed solution is separated into a hydrogen iodide solution represented by the following Reaction Formula 10 through a liquid-liquid phase separation process: Mixed solution: H2SO4+[2+(3˜4)].HI+(10˜15)I2+(20˜25).H2O  Hydrogen iodide solution after liquid-liquid phase separation: [2+(3˜4)].HI+(10˜15).I2+(15˜20).H2O  . 17. The iodine-sulfur cycle for nuclear hydrogen production according to claim 16, wherein the Reaction Formulae Reaction Formulae 3, 9 and 10 have optimal operating points represented by the Reaction Formula 6 of claim 16 and the following Reaction Formulae 11 and 12, respectively: Mixed solution: H2SO4+[2+3].HI+10.I2+20.H2O  Liquid-liquid phase separated hydrogen iodide solution: (2+3).HI+10.I2+15.H2O  . 18. The iodine-sulfur cycle for nuclear hydrogen production according to claim 13, wherein concentration of hydrogen iodide in the residual hydrogen iodide solution is a concentration at the pseudo-azeotropic point.