Integrated boiler, superheater, and decomposer for sulfuric acid decomposition
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B01J-019/00
C01B-017/48
출원번호
UP-0873451
(2007-10-17)
등록번호
US-7645437
(2010-02-22)
발명자
/ 주소
Moore, Robert
Pickard, Paul S.
Parma, Jr., Edward J.
Vernon, Milton E.
Gelbard, Fred
Lenard, Roger X.
출원인 / 주소
Sandia Corporation
대리인 / 주소
Watson, Robert D.
인용정보
피인용 횟수 :
3인용 특허 :
6
초록▼
A method and apparatus, constructed of ceramics and other corrosion resistant materials, for decomposing sulfuric acid into sulfur dioxide, oxygen and water using an integrated boiler, superheater, and decomposer unit comprising a bayonet-type, dual-tube, counter-flow heat exchanger with a catalytic
A method and apparatus, constructed of ceramics and other corrosion resistant materials, for decomposing sulfuric acid into sulfur dioxide, oxygen and water using an integrated boiler, superheater, and decomposer unit comprising a bayonet-type, dual-tube, counter-flow heat exchanger with a catalytic insert and a central baffle to increase recuperation efficiency.
대표청구항▼
What is claimed is: 1. A chemical reactor for processing a process fluid, comprising a bayonet-type, dual-tube counter-flow heat exchanger, comprising: an outer bayonet tube closed at the top and open at the bottom; an inner tube open at the top and bottom ends, and centered inside of the outer tub
What is claimed is: 1. A chemical reactor for processing a process fluid, comprising a bayonet-type, dual-tube counter-flow heat exchanger, comprising: an outer bayonet tube closed at the top and open at the bottom; an inner tube open at the top and bottom ends, and centered inside of the outer tube; for providing a return flow path from the closed end of the outer bayonet tube; an outer annular flow space formed between the inner surface of the outer bayonet tube and the outer surface of the inner tube; catalyst media disposed in the outer annular flow space near the closed end of the outer bayonet tube; a central baffle centered inside of the inner tube; and an inner annular flow space formed between the inner surface of the inner tube and the outer surface of the central baffle; wherein process fluid enters the reactor at the bottom of the outer bayonet tube, flows through the outer annular flow space towards the top of the outer bayonet tube, turns around at the top, returns back through the inner tube, flowing inside of the inner annular flow space, and exits at the bottom of the inner tube. 2. The reactor of claim 1, wherein the outer bayonet tube, inner tube, and central baffle are made of a ceramic material selected from the group consisting of silicon carbide, silicon carbide alloy, glass, quartz, and alumina. 3. The reactor of claim 1, wherein the catalyst media comprises a catalytic material selected from the group consisting of platinum, iron oxide, rhodium, and metal oxides. 4. The reactor of claim 1, wherein the radial thickness of both the outer annular flow space and the inner annular flow space are less than about 1 mm. 5. The reactor of claim 1, wherein the axial length of the catalytic media is less than or equal to ⅓ of the length of the outer bayonet tube. 6. The reactor of claim 1, wherein the inner tube has a variable diameter; and wherein the diameter of that portion of the inner tube which contacts the catalyst media is smaller than the diameter of that portion of the inner tube which does not contact the catalyst media. 7. The reactor of claim 1, wherein the reactor does not have any gaskets or seals for making fluidic connections that operate at temperatures greater than 260 C. 8. The reactor of claim 1, wherein the catalytic media extends into the plenum space located above the top of the inner tube; and a screen or porous plate covers the open top end of the inner tube for excluding catalytic media from entering the inside of the inner tube. 9. The reactor of claim 1, wherein the inner tube is transparent. 10. The reactor of claim 1, further comprising means for enhancing convective heat transfer with the process fluid selected from the group consisting of extended surfaces, internal fins, and roughened surfaces. 11. The reactor of claim 1, wherein the radial thickness of the outer annular flow space is variable, and is larger where the process fluid is substantially liquid, and is thinner where the process fluid is substantially gaseous. 12. The reactor of claim 1, wherein the central baffle comprises a solid rod. 13. The reactor of claim 1, wherein the central baffle comprises a hollow central tube with a closed upper end, and an interior volume. 14. The reactor of claim 13, wherein the hollow central baffle tube further comprises gas-selective permeable means for selectively passing one or more gaseous species from the inner annular flow space into the interior volume of the central tube. 15. The reactor of claim 13, wherein the gas-selective permeable means comprises a gas-selective membrane comprising Perovskite. 16. The reactor of claim 13, wherein the gas-selective permeable means comprises making the hollow central baffle tube out of a porous zeolite material. 17. A chemical reactor for processing a process fluid, comprising a bayonet-type, dual-tube counter-flow heat exchanger, comprising: an outer bayonet tube closed at the top and open at the bottom; an inner tube open at the top and bottom ends, and centered inside of the outer tube; for providing a return flow path from the closed end of the outer bayonet tube; an outer annular flow space formed between the inner surface of the outer bayonet tube and the outer surface of the inner tube; catalyst media disposed in the outer annular flow space near the closed end of the outer bayonet tube; a central baffle centered inside of the inner tube; and an inner annular flow space formed between the inner surface of the inner tube and the outer surface of the central baffle; wherein process fluid enters the reactor at the bottom of the outer bayonet tube, flows through the outer annular flow space towards the top of the outer bayonet tube, turns around at the top, returns back through the inner tube, flowing inside of the inner annular flow space, and exits at the bottom of the inner tube; wherein the outer bayonet tube, inner tube, and central baffle are made of a ceramic material selected from the group consisting of silicon carbide, silicon carbide alloy, glass, quartz, and alumina; wherein the catalyst media comprises a catalytic material selected from the group consisting of platinum, iron oxide, rhodium, and metal oxides; wherein the radial thickness of both the outer annular flow space and the inner annular flow space are less than about 1 mm; wherein the axial length of the catalytic media is less than or equal to ⅓ of the length of the outer bayonet tube; wherein the inner tube has a variable diameter; and wherein the diameter of that portion of the inner tube that contacts the catalyst media is smaller than the diameter of that portion of the inner tube which does not contact the catalyst media; wherein the reactor does not have any gaskets or seals for making fluidic connections that operate at temperatures greater than 260 C; and wherein the central baffle comprises a hollow central baffle tube with a closed upper end, and an interior volume. 18. A process for decomposing sulfuric acid into SO2, O2, and H2O; comprising: a) providing a chemical reactor comprising a bayonet-type, dual-tube counter-flow heat exchanger; the heat exchanger comprising: an outer bayonet tube closed at the top and open at the bottom; an inner tube open at the top and bottom ends, and centered inside of the outer tube; for providing a return flow path from the closed end of the outer bayonet tube; an outer annular flow space formed between the inner surface of the outer bayonet tube and the outer surface of the inner tube; catalyst media disposed in the outer annular flow space near the closed end of the outer bayonet tube; a central baffle centered inside of the inner tube; and an inner annular flow space formed between the inner surface of the inner tube and the outer surface of the central baffle; b) supplying heat from an outside source to the exterior surface of the outer bayonet tube; c) supplying an inlet stream of concentrated liquid sulfuric acid (H2SO4), to the outer annular flow space at the bottom of the outer bayonet tube; d) flowing the sulfuric acid in the outer annular flow space, and heating the acid beyond the boiling point to form vapors of sulfuric acid; e) superheating the vapors to at least 700 C, thereby decomposing the acid vapors into SO3 and H2O; f) passing the superheated vapors of sulfuric acid through the catalytic media, thereby forming additional decomposition products comprising SO2, O2, and H2O; g) flowing the decomposition products, including any un-reacted sulfuric acid, back down through the inner tube, through the inner annular flow space, towards the bottom of the heat exchanger; h) recuperating sensible heat from the decomposition products by transferring sensible heat from the decomposition products flowing in the inner annular flow space through the inner tube into the acid flowing in the outer annular flow space; and i) discharging the decomposition products, and any unreacted sulfuric acid, from the bottom of the heat exchanger. 19. The process of claim 18, wherein the inlet fluid temperature is less than or equal to 100 C; and the exit temperature of the decomposition products is less than or equal to 260 C. 20. The process of claim 18, wherein the temperature of the catalytic media is 700 to 900 C. 21. The process of claim 18, wherein more than 35% of the incoming sulfuric acid is decomposed into SO2, O2, and H2O decomposition products. 22. The process of claim 18, wherein 40%, or less, of the lower end of the outer bayonet tube is not externally heated. 23. A process for decomposing sulfuric acid into SO2, O2, and H2O; comprising: a) providing a chemical reactor comprising a bayonet-type, dual-tube counter-flow heat exchanger; the heat exchanger comprising: an outer bayonet tube closed at the top and open at the bottom; an inner tube open at the top and bottom ends, and centered inside of the outer tube; for providing a return flow path from the closed end of the outer bayonet tube; an outer annular flow space formed between the inner surface of the outer bayonet tube and the outer surface of the inner tube; catalyst media disposed in the outer annular flow space near the closed end of the outer bayonet tube; a central baffle centered inside of the inner tube; and an inner annular flow space formed between the inner surface of the inner tube and the outer surface of the central baffle; b) supplying heat from an outside source to the exterior surface of the outer bayonet tube; c) supplying an inlet stream of concentrated liquid sulfuric acid (H2SO4), to the outer annular flow space at the bottom of the outer bayonet tube; d) flowing the sulfuric acid in the outer annular flow space, and heating the acid beyond the boiling point to form vapors of sulfuric acid; e) superheating the vapors to at least 700 C, thereby decomposing the acid vapors into SO3 and H2O; f) passing the superheated vapors of sulfuric acid through the catalytic media, thereby forming additional decomposition products comprising SO2, O2, and H2O; g) flowing the decomposition products, including any un-reacted sulfuric acid, back down through the inner tube, through the inner annular flow space, towards the bottom of the heat exchanger; h) recuperating sensible heat from the decomposition products by transferring sensible heat from the decomposition products flowing in the inner annular flow space through the inner tube into the acid flowing in the outer annular flow space; and i) discharging the decomposition products, and any unreacted sulfuric acid, from the bottom of the heat exchanger; wherein the inlet fluid temperature is less than or equal to 100 C; and the exit temperature of the decomposition products is less than or equal to 260 C; wherein the temperature of the catalytic media is 700 to 900 C; wherein more than 35% of the incoming sulfuric acid is decomposed into SO2, O2, and H2O decomposition products; and wherein 40%, or less, of the lower end of the outer bayonet tube is not externally heated. 24. A process for decomposing sulfuric acid into SO2, O2, and H2O; comprising: a) providing a chemical reactor comprising a bayonet-type, dual-tube counter-flow heat exchanger; the heat exchanger comprising: an outer bayonet tube closed at the top and open at the bottom; an inner tube open at the top and bottom ends, and centered inside of the outer tube; for providing a return flow path from the closed end of the outer bayonet tube; an outer annular flow space formed between the inner surface of the outer bayonet tube and the outer surface of the inner tube; catalyst media disposed in the outer annular flow space near the closed end of the outer bayonet tube; a central baffle, centered inside of the inner tube; and an inner annular flow space formed between the inner surface of the inner tube and the outer surface of the central baffle; wherein the central baffle comprises a hollow central baffle tube with a closed upper end, and an interior volume; and wherein the hollow central baffle tube further comprises gas-selective permeable means for selectively passing one or more gaseous species from the inner annular flow space into the interior volume of the central tube; b) supplying heat from an outside source to the exterior surface of the outer bayonet tube; c) supplying an inlet stream of concentrated liquid sulfuric acid (H2SO4), to the outer annular flow space at the bottom of the outer bayonet tube; d) flowing the sulfuric acid in the outer annular flow space, and heating the acid beyond the boiling point to form vapors of sulfuric acid; e) superheating the vapors to at least 700 C, thereby decomposing the acid vapors into SO3 and H2O; f) passing the superheated vapors of sulfuric acid through the catalytic media, thereby forming additional decomposition products comprising SO2, O2, and H2O; g) flowing the decomposition products, including any un-reacted sulfuric acid, back down through the inner tube, through the inner annular flow space, towards the bottom of the heat exchanger; h) recuperating sensible heat from the decomposition products by transferring sensible heat from the decomposition products flowing in the inner annular flow space through the inner tube into the acid flowing in the outer annular flow space; i) selectively separating, using the gas-selective permeable means, at least one gaseous species of decomposition product from the inner annular flow space into the interior volume of the hollow central baffle tube; j) discharging the separated-out at least one gaseous species of decomposition product from the interior volume of the hollow central baffle tube at the bottom of the heat exchanger; and k) discharging, as a separate stream from the stream in step j), the remaining un-separated decomposition products, plus any unreacted sulfuric acid, from the inner annular flow space, at the bottom of the heat exchanger. 25. The process of claim 23, wherein the gas-selective permeable means selectively passes SO2 gas through it, but not O2 or H2O.
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이 특허에 인용된 특허 (6)
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