Methods and apparatus for solid carbonaceous materials synthesis gas generation
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
C01B-003/02
B01J-019/00
출원번호
UP-0296202
(2007-04-11)
등록번호
US-7857995
(2011-02-24)
국제출원번호
PCT/US2007/066466
(2007-04-11)
§371/§102 date
20081006
(20081006)
국제공개번호
WO07/121268
(2007-10-25)
발명자
/ 주소
Johnson, Dennis E. J.
Abramov, Grigori A.
Kleinke, Richard A.
Wiley, Marcus A.
출원인 / 주소
Thermo Technologies, LLC
대리인 / 주소
Santangelo Law Offices, P.C.
인용정보
피인용 횟수 :
16인용 특허 :
30
초록▼
Methods and apparatus may permit the generation of consistent output synthesis gas from highly variable input feedstock solids carbonaceous materials. A stoichiometric objectivistic chemic environment may be established to stoichiometrically control carbon content in a solid carbonaceous materials g
Methods and apparatus may permit the generation of consistent output synthesis gas from highly variable input feedstock solids carbonaceous materials. A stoichiometric objectivistic chemic environment may be established to stoichiometrically control carbon content in a solid carbonaceous materials gasifier system. Processing of carbonaceous materials may include dominative pyrolytic decomposition and multiple coil carbonaceous reformation. Dynamically adjustable process determinative parameters may be utilized to refine processing, including process utilization of negatively electrostatically enhanced water species, process utilization of flue gas (9), and adjustment of process flow rate characteristics. Recycling may be employed for internal reuse of process materials, including recycled negatively electrostatically enhanced water species, recycled flue gas (9), and recycled contaminants. Synthesis gas generation may involve predetermining a desired synthesis gas for output and creating high yields of such a predetermined desired synthesis gas.
대표청구항▼
What is claimed is: 1. A method for select synthesis gas generation from solid carbonaceous materials comprising the steps of: inputting a feedstock solids carbonaceous material; subjecting said feedstock solids carbonaceous material to a pressurized environment; intentionally establishing stoichio
What is claimed is: 1. A method for select synthesis gas generation from solid carbonaceous materials comprising the steps of: inputting a feedstock solids carbonaceous material; subjecting said feedstock solids carbonaceous material to a pressurized environment; intentionally establishing stoichiometric carbon conversion conditions for said feedstock solids carbonaceous material in said pressurized environment; stoichiometrically controlling carbon content relative to a target carbon content for a select product gas; increasing an temperature within said pressurized environment to which said feedstock solids carbonaceous material is subjected; pyrolytically decomposing at least a portion of said feedstock solids carbonaceous material in a solid carbonaceous materials gasifier system; creating a pyrolytically decomposed carbonaceous material; processing said pyrolytically decomposed carbonaceous material in said solid carbonaceous materials gasifier system; generating at least some components of a select product gas in response to said step of processing said pyrolytically decomposed carbonaceous material; outputting at least some select product gas from said solid carbonaceous materials gasifier system. 2. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise the step of varying said input feedstock solids carbonaceous material. 3. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 2 wherein said step of varying said input feedstock solids carbonaceous material comprises the step of varying selected from the group consisting of: varying a carbon content, varying an oxygen content, varying a hydrogen content, varying a water content, varying a particle size property, varying a hardness property, varying a density property, varying a wood waste content, varying a municipal solid waste content, varying a garbage content, varying a sewage solids content, varying a manure content, varying a biomass content, varying a rubber content, varying a coal content, varying a petroleum coke content, varying a food waste content, and varying an agricultural waste content. 4. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of outputting at least some select product gas comprises the step of varying said output select product gas. 5. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 4 wherein said step of varying said output select product gas comprises the step of varying selected from the group consisting of: varying a carbon monoxide content of a select product gas, outputting a primarily carbon monoxide select product gas, varying a hydrogen content of a select product gas, outputting a primarily hydrogen gas select product gas, varying a methane content of a select product gas, outputting a primarily methane select product gas, outputting a select product gas of primarily carbon monoxide and hydrogen gas and methane, controlling a molar ratio of a select product gas, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of from 1:1 up to 20:1 by volume, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 1:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 2:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 3:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 5:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 10:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 1:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 2:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 3:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 5:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 10:1 to about 20:1,outputting producer gas, outputting synthesis gas, outputting a variable chemistry base stock, outputting a liquid fuel base stock, outputting a methanol base stock, outputting an ethanol base stock, outputting a refinery diesel base stock, outputting a biodiesel base stock, outputting a dimethyl-ether base stock, outputting a mixed alcohols base stock, outputting an electric power generation base stock., and outputting a natural gas equivalent energy value base stock. 6. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise the steps of selecting a product gas to output, evaluating a feedstock solids carbonaceous material input, and determining a chemical reaction sequence appropriate to yield said select product gas from said feedstock solids carbonaceous material. 7. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 6 further comprising the step of supplying chemical reactants selected from the group consisting of: supplying chemical reactants sufficient to satisfy the molar ratios of said chemical reaction sequence, supplying chemical reactants sufficient to substantially completely chemically react said feedstock solids carbonaceous material, supplying chemical reactants sufficient to produce a high output of said select product gas, and supplying chemical reactants sufficient to temporally accelerate said chemical reaction sequence. 8. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise the step of injecting a flue gas. 9. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 8 wherein said step of injecting a flue gas comprises the step of pressurizing said flue gas. 10. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 9 wherein said step of pressurizing said flue gas comprises the step of pressurizing said flue gas to at least 80 psi. 11. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 8 wherein said step of injecting a flue gas comprises the step of preheating said flue gas. 12. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 11 wherein said step of preheating said flue gas comprises the step of preheating to a temperature selected from the group consisting of: preheating to at least 125 degrees Fahrenheit, preheating to at least 135 degrees Fahrenheit, preheating to at least 300 degrees Fahrenheit, preheating to at least 600 degrees Fahrenheit, and preheating to at least 1640 degrees Fahrenheit. 13. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 11 wherein said step of preheating said flue gas comprises the step of preheating in a gasifier system process enclosure. 14. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 8 wherein said step of injecting a flue gas comprises the step of recycling said flue gas. 15. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 14 wherein said step of recycling said flue gas comprises the step of recycling selected from the group consisting of: recycling to a pretreatment area, recycling to a pyrolysis chamber, recycling to a multiple coil carbonaceous reformation vessel, recycling to a preliminary reformation coil of a multiple coil carbonaceous reformation vessel, recycling to a secondary reformation coil of a multiple coil carbonaceous reformation vessel, and recycling to a tertiary coil of a multiple coil carbonaceous reformation vessel. 16. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 8 wherein said step of injecting a flue gas comprises the step of affecting at least one process determinative parameter. 17. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 16 wherein said step of affecting comprises the step of affecting selected from the group consisting of: raising a temperature, maintaining a pressure, raising a pressure, chemically reacting, temporally accelerating a chemical reaction sequence, displacing at least some oxygen content from a feedstock solids carbonaceous material, displacing at least some water content from a feedstock solids carbonaceous material, intentionally establishing stoichiometric carbon conversion conditions for said feedstock solids carbonaceous material, and stoichiometrically controlling carbon content. 18. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise the step of purging process superfluous materials. 19. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 18 wherein said step of purging process superfluous materials comprises the step of purging selected from the group consisting of: purging oxygen and purging nitrogen. 20. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 18 wherein said step of purging process superfluous materials comprises the steps of oxidizing metals and electrostatically attracting said oxidized metals. 21. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise the step of adding process beneficial materials. 22. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 21 wherein said step of adding process beneficial materials comprises the step of adding selected from the group consisting of: adding carbon, adding hydrogen, adding carbon monoxide, adding carbon dioxide, adding water, adding preheated water, adding a negatively electrostatically enhanced water species, adding steam, adding negatively electrostatically enhanced steam, adding recycled select product gas, adding wet recycled select product gas, and adding dry recycled select product gas. 23. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise the step of recycling. 24. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 23 wherein said step of recycling comprises the step of recycling selected from the group consisting of: recycling carbon dioxide, recycling water, recycling preheated water, recycling a negatively electrostatically enhanced water species, recycling a preheated negatively electrostatically enhanced water species, recycling steam, recycling negatively electrostatically enhanced steam, recycling an incompletely pyrolytically decomposed carbonaceous material, recycling carbon monoxide, recycling select product gas, recycling wet select product gas, recycling dry select product gas, recycling carbonaceous particles of at least 350 micron particle size, recycling carbonaceous particles of at least 150 micron particle size, recycling carbonaceous particles of at least 130 micron particle size, recycling carbonaceous particles of at least 80 micron particle size, recycling carbonaceous particles of at least 50 micron particle size, recycling to a pretreatment area, recycling to a pyrolysis chamber, and recycling to a multiple coil carbonaceous reformation vessel. 25. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise the steps of sensing at least one process condition and responsively dynamically adjusting at least one process determinative parameter. 26. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise the steps of establishing a process set point, periodically testing at least one process condition, and responsively dynamically adjusting at least one process determinative parameter. 27. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise the steps of evaluating said feedstock solids carbonaceous material and responsively dynamically adjusting at least one process determinative parameter. 28. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise the step of removing water at a water critical pass through. 29. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said steps of intentionally establishing stoichiometric carbon conversion conditions and stoichiometrically controlling carbon content comprise a step selected from the group consisting of: preheating said feedstock solids carbonaceous material, controlling an oxygen content of said feedstock solids carbonaceous material, and pyrolytically decomposing said feedstock solids carbonaceous material. 30. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 further comprising the step of creating a high energy content select product gas. 31. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 30 wherein said step of creating a high energy content select product gas comprises a step selected from the group consisting of: processing with a negatively electrostatically enhanced water species, processing with a recycled select product gas, processing with negatively electrostatically enhanced steam, processing with a flue gas, varying a process retention time, processing in at least a preliminary reformation coil and a secondary reformation coil, recycling an incompletely pyrolytically decomposed carbonaceous material, and recycling an incompletely reformed carbonaceous material. 32. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 30 wherein said step of creating a high energy content select product gas comprises the step of dominatively pyrolytically decomposing said feedstock solids carbonaceous material. 33. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 30 wherein said step of creating a high energy content select product gas comprises the step of purifying said select product gas. 34. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 33 wherein said step of purifying said select product gas comprises the step of removing at least one contaminant from said select product gas. 35. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 30 wherein said step of creating a high energy content select product gas comprises a step selected from the group consisting of producing a select product gas having a BTU value of at least 250 BTU per standard cubic foot, producing a select product gas having a BTU value of at least 350 BTU per standard cubic foot, producing a select product gas having a BTU value of at least 450 BTU per standard cubic foot, producing a select product gas having a BTU value of at least 550 BTU per standard cubic foot, producing a select product gas having a BTU value of at least 650 BTU per standard cubic foot, producing a select product gas having a BTU value of at least 750 BTU per standard cubic foot, producing a select product gas having a BTU value from about 250 BTU per standard cubic foot to about 750 BTU per standard cubic foot, producing a select product gas having a BTU value from about 350 BTU per standard cubic foot to about 750 BTU per standard cubic foot, producing a select product gas having a BTU value from about 450 BTU per standard cubic foot to about 750 BTU per standard cubic foot, producing a select product gas having a BTU value from about 550 BTU per standard cubic foot to about 750 BTU per standard cubic foot, producing a select product gas having a BTU value from about 650 BTU per standard cubic foot to about 750 BTU per standard cubic foot. 36. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 35 further comprising the step of varying an output quantity of said produced select product gas in proportion to an energy content of said feedstock solids carbonaceous material. 37. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 further comprising the step of dynamically adjusting at least one process determinative parameter within said solid carbonaceous materials gasifier system. 38. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 37 wherein said step of dynamically adjusting comprises the steps of sensing at least one process condition and responsively dynamically adjusting at least one process determinative parameter within said solid carbonaceous materials gasifier system. 39. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 38 wherein said step of sensing at least one process condition comprises the step of sensing selected from the group consisting of: sensing a temperature, sensing a pressure, sensing a process materials composition, sensing a carbon monoxide content, sensing a carbon dioxide content, sensing a hydrogen content, sensing a nitrogen content, sensing sulfur content, sensing via a gas chromatograph, and sensing via a mass spectrometer. 40. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 38 wherein said step of responsively dynamically adjusting at least one process determinative parameter comprises the step of responsively dynamically adjusting selected from the group consisting of: responsively dynamically adjusting at an input environment, responsively dynamically adjusting at a pretreatment area, responsively dynamically adjusting at a pyrolysis chamber, responsively dynamically adjusting at a multiple coil carbonaceous reformation vessel, and responsively dynamically adjusting at a select product gas components scrubber. 41. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 38 wherein said step of responsively dynamically adjusting at least one process determinative parameter comprises the step of responsively dynamically adjusting selected from the group consisting of: adding water, adding prehated water, adding recycled water, adding a negatively electrostatically enhanced water species, adding a preheated negatively electrostatically enhanced water species, adding a recycled negatively electrostatically enhanced water species, adding steam, adding recycled steam, adding negatively electrostatically enhanced steam, adding recycled negatively electrostatically enhanced steam, adding flue gas, adding preheated flue gas, adding pressurized flue gas, adding recycled flue gas, adding a recycled incompletely pyrolytically decomposed carbonaceous material, adding a recycled incompletely reformed carbonaceous material, adding at least one recycled contaminant, adding at least some select product gas, adding at least some wet product gas, adding at least some dry select product gas, adding at least some recycled select product gas, varying a process retention time, varying a process flow rate, varying a process flow turbulence, varying a process flow cavitation, varying a selectively applied heat distribution among multiple reformation coils, varying a temperature gradient in a temperature varied environment, varying a liquefaction zone in a temperature varied environment, and selectively separating a carbonaceously reformed material. 42. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 38 wherein said step of responsively dynamically adjusting at least one process determinative parameter comprises the step of responsively dynamically adjusting selected from the group consisting of: automatically responsively dynamically adjusting and computer controlling a responsive dynamic adjustment. 43. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 42 wherein said step of responsively dynamically adjusting comprises responsively dynamically adjusting selected from the group consisting of: responsively dynamically adjusting in less than 0.5 seconds, responsively dynamically adjusting in less than 1 second, responsively dynamically adjusting in less than 2 seconds, responsively dynamically adjusting in less than 3 seconds, responsively dynamically adjusting in less than 4 seconds, responsively dynamically adjusting in less than 5 seconds, responsively dynamically adjusting in less than 10 seconds, responsively dynamically adjusting in less than 15 seconds, responsively dynamically adjusting in less than 30 seconds, responsively dynamically adjusting in less than 45 seconds, responsively dynamically adjusting in less than 60 seconds, and responsively dynamically adjusting in less than 90 seconds. 44. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 38 wherein said step of responsively dynamically adjusting at least one process determinative parameter further comprises the steps of establishing a process set point and periodically testing a process condition. 45. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 38 wherein said step of responsively dynamically adjusting at least one process determinative parameter further comprises the step of evaluating said feedstock solids carbonaceous material. 46. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 38 wherein said step of responsively dynamically adjusting at least one process determinative parameter comprises the step of affecting said select product gas. 47. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 46 wherein said step of affecting said select product gas comprises a step selected from the group consisting of: increasing the purity of said select product gas, increasing the BTU value of said select product gas, facilitating production of a select product gas having a BTU value of at least 250 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value of at least 350 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value of at least 450 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value of at least 550 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value of at least 650 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value of at least 750 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value from about 250 BTU per standard cubic foot to about 750 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value from about 350 BTU per standard cubic foot to about 750 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value from about 450 BTU per standard cubic foot to about 750 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value from about 550 BTU per standard cubic foot to about 750 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value from about 650 BTU per standard cubic foot to about 750 BTU per standard cubic foot. 48. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of outputting at least some select product gas comprises the step of predetermining a desired select product gas for output. 49. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 48 wherein said step of predetermining a desired select product gas for output comprises the step of predetermining selected from the group consisting of: varying a carbon monoxide content of a select product gas, outputting a primarily carbon monoxide select product gas, varying a hydrogen content of a select product gas, outputting a primarily hydrogen gas select product gas, varying a methane content of a select product gas, outputting a primarily methane select product gas, outputting a select product gas of primarily carbon monoxide and hydrogen gas and methane, controlling a molar ratio of a select product gas, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of from 1:1 up to 20:1 by volume, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 1:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 2:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 3:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 5:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 10:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 1:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 2:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 3:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 5:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 10:1 to about 20:1,outputting producer gas, outputting synthesis gas, outputting a variable chemistry base stock, outputting a liquid fuel base stock, outputting a methanol base stock, outputting an ethanol base stock, outputting a refinery diesel base stock, outputting a biodiesel base stock, outputting a dimethyl-ether base stock, outputting a mixed alcohols base stock, outputting an electric power generation base stock., and outputting a natural gas equivalent energy value base stock. 50. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 48 further comprising the step of outputting said predetermined select product gas by affirmatively establishing a stoichiometrically objectivistic chemic environment and stoichiometrically controlling carbon content for said feedstock solids carbonaceous material in said pressurized environment. 51. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 48 further comprising the step of outputting said predetermined select product gas by dynamically adjusting at least one process determinative parameter within said solid carbonaceous materials gasifier system. 52. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of outputting at least some select product gas comprises the step of exceeding a typical yield. 53. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 52 wherein said step of exceeding a typical yield comprises the step of substantially exhausting a carbon content of said feedstock solids carbonaceous material. 54. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 52 wherein said step of exceeding a typical yield comprises the step selected from the group consisting of: achieving a feedstock mass conversion efficiency of at least about 95%, achieving a feedstock mass conversion efficiency of at least about 97%, and achieving a feedstock mass conversion efficiency of at least about 98%. 55. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 52 wherein said step of exceeding a typical yield comprises the step of outputting at least about 30,000 standard cubic feet of select product gas per ton of feedstock solids carbonaceous material. 56. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 52 wherein said step of exceeding a typical yield comprises the step of achieving a carbon conversion efficiency of said feedstock solids carbonaceous material of between 75% and 95%. 57. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 further comprising the step of magnetically isolating at least one constituent component of said feedstock solids carbonaceous material. 58. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 57 wherein said step of magnetically isolating comprises the step of magnetically attracting a metallic constituent component of said feedstock solids carbonaceous material. 59. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 57 wherein said step of magnetically isolating comprises the steps of oxidizing said constituent component, creating a metal oxide of said constituent component, and magnetically attracting said metal oxide. 60. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 57 wherein said step of magnetically isolating comprises the steps of reacting said constituent component with a negatively electrostatically enhanced water species and magnetically attracting said reacted constituent component. 61. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 57 wherein said step of magnetically isolating comprises the step of magnetically enhancing a gravimetric deflection of said constituent component. 62. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 57 wherein said step of magnetically isolating comprises the step of receiving said constituent component in an electromagnetic drop well. 63. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 57 wherein said step of magnetically isolating comprises the step of reducing abrasion within said solid carbonaceous materials gasifier system. 64. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 57 wherein said step of magnetically isolating comprises the step of magnetically isolating at least one contaminant. 65. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 64 further comprising a step selected from the group consisting of: increasing the purity of a select product gas, increasing the BTU value of a select product gas, facilitating production of a select product gas having a BTU value of at least 250 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value of at least 350 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value of at least 450 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value of at least 550 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value of at least 650 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value of at least 750 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value from about 250 BTU per standard cubic foot to about 750 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value from about 350 BTU per standard cubic foot to about 750 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value from about 450 BTU per standard cubic foot to about 750 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value from about 550 BTU per standard cubic foot to about 750 BTU per standard cubic foot, facilitating production of a select product gas having a BTU value from about 650 BTU per standard cubic foot to about 750 BTU per standard cubic foot. 66. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 further comprising the steps of preliminarily carbonaceously reforming said feedstock solids carbonaceous material in a preliminary reformation coil, secondarily carbonaceously reforming said feedstock solids carbonaceous material in a secondary reformation coil, and complementarily configuring said preliminary reformation coil and said secondary reformation coil. 67. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 66 further comprising the steps of tertiarily carbonaceously reforming said feedstock solids carbonaceous material in a tertiary reformation coil and complementarily configuring said tertiary reformation coil. 68. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 66 or 67 wherein said step of complementarily configuring comprises the step of helically nesting at least two said reformation coils. 69. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 68 further comprising the steps of applying heat to said reformation coils and selectively distributing said applied heat among said reformation coils. 70. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 69 wherein said step of selectively distributing said applied heat comprises the step of radiating said applied heat from at least one said reformation coil to at least one other said reformation coil. 71. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 70 wherein said step of radiating said applied heat comprises the step of variably triply distributing said applied heat among said reformation coils. 72. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 further comprising the step of reducing nitrogen content within said solid carbonaceous materials gasifier system. 73. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 72 wherein said step of reducing nitrogen content comprises the step of inputting air into an air separation unit of said solid carbonaceous materials gasifier system and depleting nitrogen content from said air. 74. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 73 further comprising the step of increasing oxygen content to a combustive burner of said solid carbonaceous materials gasifier system and reducing a recycle requirement of select product gas to said combustive burner. 75. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 73 further comprising a step selected from the group consisting of: increasing oxygen content to a negatively electrostatically enhanced water species generation unit integrated with said solid carbonaceous materials gasifier system and increasing activated oxygen content to a negatively electrostatically enhanced water species generation unit integrated with said solid carbonaceous materials gasifier system. 76. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 73 further comprising the step of reducing nitrogen contaminants selected from the group consisting of: reducing nitrogen contaminants within said solid carbonaceous materials gasifier system, reducing nitrogen contaminants within said select product gas, and reducing nitrogen contaminants within emissions from said solid carbonaceous materials gasifier system. 77. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 further comprising the step of displacing at least some oxygen content from said feedstock solids carbonaceous material prior to a selected step of processing said feedstock solids carbonaceous material. 78. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 77 wherein said step of displacing at least some oxygen content comprises the step of displacing at a pretreatment area. 79. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 77 wherein said step of displacing at least some oxygen content comprises the step of displacing air. 80. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 77 wherein said step of displacing at least some oxygen content comprises the step of displacing selected from the group consisting of: using flue gas, using pressurized flue gas, using preheated flue gas, using recycled flue gas, using select product gas, using wet select product gas, using dry select product gas, using recycled select product gas, pressurizing to at least 40 psi, and preheating to at least 300 degrees Fahrenheit. 81. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 77 wherein said step of displacing at least some oxygen content comprises the step of displacing selected from the group consisting of: gravimetrically displacing, injecting a flue gas at the bottom of an incline and releasing oxygen at the top of said incline, and injecting a select product gas at the bottom of an incline and releasing said oxygen at the top of said incline. 82. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 further comprising the step of selectively adjusting a process flow rate. 83. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 82 wherein said step of selectively adjusting a process flow rate comprises the step of regulating a pressure to velocity ratio for a multiple coil carbonaceous reformation vessel selected from the group consisting of: maintaining a pressure of at least 80 psi, maintaining a flow rate of at least 5,000 feet per minute, and maintaining a Reynolds number value of at least 20,0000. 84. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 82 wherein said step of selectively adjusting a process flow rate comprises the steps of dominatively pyrolytically decomposing said feedstock solids carbonaceous material and acceleratedly carbonaceously reforming said dominatively pyrolytically decomposed feedstock solids carbonaceous material. 85. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 84 wherein said step of dominatively pyrolytically decomposing comprises the step of retaining said feedstock solids carbonaceous material in a pyrolysis chamber selected from the group consisting of: retaining for at least 2 minutes, retaining for at least 3 minutes, retaining for at least 4 minutes, retaining for at least 5 minutes, retaining for at least 6 minutes, retaining for at least 7 minutes, retaining for at least 8 minutes, retaining for at least 9 minutes, retaining for at least 10 minutes, retaining for at least 11 minutes, retaining for at least 12 minutes, retaining for at least 13 minutes, retaining for at least 14 minutes, retaining for at least 15 minutes, retaining for at least 16 minutes, retaining for at least 17 minutes, retaining for at least 18 minutes, retaining for at least 19 minutes, and retaining for at least 20 minutes, and wherein said step of acceleratedly carbonaceously reforming said dominatively pyrolytically decomposed feedstock solids carbonaceous material comprises the step of reforming in a multiple coil carbonaceous reformation vessel for about 4 seconds to about 10 seconds. 86. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 further comprising the step of venturi injector regulating a process flow rate. 87. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 86 wherein said step of venturi injector regulating comprises the step of selectively adjusting a process flow rate. 88. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 86 wherein said step of venturi injector regulating comprises the steps of venturi injector injecting a substance into a process flow and venturi injector cavitating said process flow. 89. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 88 wherein said step of venturi injector injecting comprises the step of tangentially injecting at a venturi injector throat, and wherein said step of venturi injector cavitating comprises the step of rotationally turbulently mixing said process flow. 90. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 88 wherein said step of venturi injector cavitating further comprises the step of impeding said process flow with a stop block ring. 91. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 88 wherein said step of venturi injector injecting comprises the step of injecting selected from the group consisting of: injecting a flue gas, injecting a pressurized flue gas, injecting a preheated flue gas, injecting a recycled flue gas, injecting water, injecting preheated water, injecting recycled water, injecting a negatively electrostatically enhanced water species, injecting a preheated negatively electrostatically enhanced water species, injecting a recycled negatively electrostataically enhanced water species, injecting steam, injecting recycled steam, injecting negatively electrostatically enhanced steam, injecting recycled negatively electrostatically enhanced steam, injecting select product gas, injecting wet select product gas, injecting dry select product gas, and injecting recycled select product gas. 92. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 89 further comprising the step of substantially mixing said venturi injector injected substance and said process flow. 93. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 92 wherein said step of substantially mixing said venturi injector injected substance and said process flow comprises the step of substantially mixing selected from the group consisting of: mixing to at least 90% mixed, mixing to at least 91% mixed, mixing to at least 92% mixed, mixing to at least 93% mixed, mixing to at least 94% mixed, mixing to at least 95% mixed, mixing to at least 96% mixed, mixing to at least 97% mixed, mixing to at least 98% mixed, and mixing to at least 99% mixed. 94. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 86 further comprising the step of selectively placing at least one said venturi injector relative to said process flow. 95. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 94 wherein said step of selectively placing at least one said venturi injector comprises the step of selectively placing multiple venturi injectors relative to said process flow. 96. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 further comprising the steps of producing flue gas within said solid carbonaceous materials gasifier system and injecting said flue gas back into said solid carbonaceous materials gasifier system at the point of at least one selected location. 97. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 96 wherein said step of injecting a flue gas comprises the step of pressurizing said flue gas. 98. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 97 wherein said step of pressurizing said flue gas comprises the step of pressurizing said flue gas to at least 80 psi. 99. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 96 wherein said step of injecting a flue gas comprises the step of preheating said flue gas. 100. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 99 wherein said step of preheating said flue gas comprises the step of preheating to a temperature selected from the group consisting of: preheating to at least 125 degrees Fahrenheit, preheating to at least 135 degrees Fahrenheit, preheating to at least 300 degrees Fahrenheit, preheating to at least 600 degrees Fahrenheit, and preheating to at least 1640 degrees Fahrenheit. 101. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 99 wherein said step of preheating said flue gas comprises the step of preheating in a gasifier system process enclosure. 102. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 96 wherein said step of injecting a flue gas comprises the step of recycling said flue gas. 103. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 102 wherein said step of recycling said flue gas comprises the step of recycling selected from the group consisting of: recycling to a pretreatment area, recycling to a pyrolysis chamber, recycling to a multiple coil carbonaceous reformation vessel, recycling to a preliminary reformation coil of a multiple coil carbonaceous reformation vessel, recycling to a secondary reformation coil of a multiple coil carbonaceous reformation vessel, and recycling to a tertiary reformation coil of a multiple coil carbonaceous reformation vessel. 104. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 96 wherein said step of injecting a flue gas comprises the step of affecting at least one process determinative parameter. 105. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 104 wherein said step of affecting comprises the step of affecting selected from the group consisting of: raising a temperature, maintaining a pressure, raising a pressure, chemically reacting, temporally accelerating a chemical reaction sequence, displacing at least some oxygen content from a feedstock solids carbonaceous material, displacing at least some water content from a feedstock solids carbonaceous material, affirmatively establishing a stoichiometrically objectivistic chemic environment, and stoichiometrically controlling carbon content. 106. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of inputting a feedstock solids carbonaceous material comprises the step of inputting selected from the group consisting of: inputting a variable carbon content, inputting a variable oxygen content, inputting a variable hydrogen content, inputting a variable water content, inputting a variable particle size property, inputting a variable hardness property, inputting a variable density property, inputting a variable wood waste content, inputting a variable municipal solid waste content, inputting a variable garbage content, inputting a variable sewage solids content, inputting a variable manure content, inputting a variable biomass content, inputting a variable rubber content, inputting a variable coal content, inputting a variable petroleum coke content, inputting a variable food waste content, and inputting a variable agricultural waste content. 107. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of inputting a feedstock solids carbonaceous material comprises the step of milling said feedstock solids carbonaceous material selected from the group consisting of: milling to a process flow size and milling to less than about 2 cubic inches. 108. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of inputting a feedstock solids carbonaceous material comprises the step of inputting a non-slurried carbonaceous feedstock. 109. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of subjecting said feedstock solids carbonaceous material to a pressurized environment comprises the step of subjecting said feedstock solids carbonaceous material to a pressurized environment selected from the group utilizing an airlock, utilizing a double airlock, subjecting in a pretreatment area enclosure, subjecting in a pyrolysis chamber enclosure, subjecting in a multiple coil carbonaceous reformation vessel enclosure, and subjecting in a solid carbonaceous materials gasifier system enclosure. 110. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of subjecting said feedstock solids carbonaceous material to a pressurized environment comprises the step of sealing said feedstock solids carbonaceous material within said pressurized environment. 111. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of increasing an temperature comprises the step of increasing an temperature selected from the group consisting of: increasing a pretreatment temperature, increasing a pyrolytic decomposition temperature, increasing a carbonaceous reformation temperature, increasing from about 125 degrees Fahrenheit to about 135 degrees Fahrenheit, increasing from about 135 degrees Fahrenheit to about 300 degrees Fahrenheit, increasing from about 300 degrees Fahrenheit to about 1000 degrees Fahrenheit, increasing from about 1000 degrees Fahrenheit to about 1640 degrees Fahrenheit, and increasing from about 1640 degrees Fahrenheit to about 1850 degrees Fahrenheit. 112. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of pyrolytically decomposing comprises the step of vaporizing at least some of said feedstock solids carbonaceous material selected from the group consisting of: vaporizing hydrocarbons and vaporizing select product gas components. 113. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of generating at least some components of a select product gas comprises the step of generating selected from the group consisting of: generating carbon monoxide content, generating hydrogen content, and generating a 1:1 molar ratio content of carbon monoxide to hydrogen. 114. A method for select synthesis gas generation from solid carbonaceous materials as described in claim 1 wherein said step of outputting at least some select product gas comprises the step of outputting selected from the group consisting of: varying a carbon monoxide content of a select product gas, outputting a primarily carbon monoxide select product gas, varying a hydrogen content of a select product gas, outputting a primarily hydrogen gas select product gas, varying a methane content of a select product gas, outputting a primarily methane select product gas, outputting a select product gas of primarily carbon monoxide and hydrogen gas and methane, controlling a molar ratio of a select product gas, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of from 1:1 up to 20:1 by volume, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 1:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 2:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 3:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 5:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio of at least about 10:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 1:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 2:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 3:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 5:1 to about 20:1, outputting a select product gas having a controlled hydrogen gas to carbon monoxide molar ratio from at least about 10:1 to about 20:1,outputting producer gas, outputting synthesis gas, outputting a variable chemistry base stock, outputting a liquid fuel base stock, outputting a methanol base stock, outputting an ethanol base stock, outputting a refinery diesel base stock, outputting a biodiesel base stock, outputting a dimethyl-ether base stock, outputting a mixed alcohols base stock, outputting an electric power generation base stock, and outputting a natural gas equivalent energy value base stock.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (30)
Johnson Dennis E. J., Apparatus and processes for non-chemical plasma ion disinfection of water.
Collin Per Harald (Falun SW), Apparatus for and process of converting carbonaceous materials containing sulphur to an essentially sulphur-free combust.
Johnson Dennis E. J. (Aurora IL), Electro-coalescence/magnetic separation (ECMS) system and components for removal of contaminants from water streams, inc.
Johnson Dennis E. J. (Aurora IL), Method and apparatus for water treatment and purification using gas ion plasma source and disinfectant metal ion complex.
Johnson Dennis E. J. (Colorado Springs CO) Frith Clifford F. (Boulder CO), Method for mixing coagulating agents into a contaminated water flow, and for removing contaminants therefrom.
Johnson Dennis E. J. (8530 Windfall Way Black Forest CO 80908), Method for water treatment and purification using gas ion plasma source and disinfectant metal ion complexes.
Johnson, Dennis E. J.; Abramov, Grigori A.; Kleinke, Richard A.; Wiley, Marcus A., Methods and apparatus for solid carbonaceous materials synthesis gas generation.
Babu Suresh P. (Willow Springs IL) Anderson Gerald L. (Romeoville IL) Nandi Satyendra P. (Downers Grove IL), Process for gasification of cellulosic biomass.
Babu Suresh P. (Willow Springs IL) Anderson Gerald L. (Romeoville IL) Nandi Satyendra P. (Downers Grove IL), Process for gasification of cellulosic materials.
Stickler David B. (Belmont Carlisle MA) Von Rosenberg ; Jr. Charles W. (Belmont Andover MA) Gannon Richard E. (Andover MA), Subsonic-velocity entrained-bed gasification of coal.
Johnson Dennis E. J. (Englewood CO) Frith Clifford F. (Boulder CO), System and reactor for mixing coagulating agents into a contaminated water flow, and for removing contaminants therefrom.
Purdy Kenneth R. (Decatur GA) Gorton Charles W. (Atlanta GA) Knight ; Jr. James A. (Atlanta GA), Thermochemical conversion of biomass to syngas via an entrained pyrolysis/gasification process.
Johnson Dennis E. J. (Aurora IL), Ultraviolet sterilizer and source of ionized molecules for electrocoalescent/magnetic separation (ECMS) removal of conta.
Von Rosenberg ; Jr. Charles W. (Belmont MA) Stickler David B. (Carlisle MA) Gannon Richard E. (Andover MA), Very-high-velocity entrained-bed gasification of coal.
Chandran, Ravi; Burciaga, Daniel A.; Leo, Daniel Michael; Freitas, Shawn Robert; Newport, Dave G.; Miller, Justin Kevin; Harrington, Kaitlin Emily; Attwood, Brian Christopher; Schultheis, Emily Jane; Kishton, Kelly Ann, Feed zone delivery system having carbonaceous feedstock density reduction and gas mixing.
Chandran, Ravi; Burciaga, Daniel A.; Leo, Daniel Michael; Freitas, Shawn Robert; Newport, Dave G.; Miller, Justin Kevin; Harrington, Kaitlin Emily; Attwood, Brian Christopher; Schultheis, Emily Jane; Kishton, Kelly Ann, Feedstock delivery system having carbonaceous feedstock splitter and gas mixing.
Chandran, Ravi; Newport, Dave G.; Burciaga, Daniel A.; Leo, Daniel Michael; Miller, Justin Kevin; Harrington, Kaitlin Emily; Attwood, Brian Christopher, Liquid fuel production system having parallel product gas generation.
Chandran, Ravi; Leo, Daniel Michael; Freitas, Shawn Robert; Newport, Dave G.; Whitney, Hamilton Sean Michael; Burciaga, Daniel A., Method for converting biomass into fischer-tropsch products with carbon dioxide recycling.
Chandran, Ravi; Burciaga, Daniel A.; Leo, Daniel Michael; Freitas, Shawn Robert; Newport, Dave G.; Miller, Justin Kevin; Harrington, Kaitlin Emily; Attwood, Brian Christopher; Schultheis, Emily Jane; Kishton, Kelly Ann, Method for forming a plurality of plugs of carbonaceous material.
Johnson, Dennis E. J.; Abramov, Grigori A.; Kleinke, Richard A.; Wiley, Marcus A., Methods and apparatus for solid carbonaceous materials synthesis gas generation.
Johnson, Dennis E. J.; Abramov, Grigori A.; Kleinke, Richard A.; Wiley, Marcus A., Methods and apparatus for solid carbonaceous materials synthesis gas generation.
Johnson, Dennis E. J.; Abramov, Grigori A.; Kleinke, Richard A.; Wiley, Marcus A., Methods and apparatus for solid carbonaceous materials synthesis gas generation.
Johnson, Dennis E. J.; Abramov, Grigori A.; Kleinke, Richard A.; Wiley, Marcus A., Methods and apparatus for solid carbonaceous materials synthesis gas generation.
Chandran, Ravi; Newport, Dave G.; Burciaga, Daniel A.; Leo, Daniel Michael; Miller, Justin Kevin; Harrington, Kaitlin Emily; Attwood, Brian Christopher; Whitney, Hamilton Sean Michael, Pulse combustion heat exchanger system and method.
Chandran, Ravi; Burciaga, Daniel A.; Leo, Daniel Michael; Freitas, Shawn Robert; Newport, Dave G.; Miller, Justin Kevin; Harrington, Kaitlin Emily; Attwood, Brian Christopher, Two-stage energy-integrated product gas generation system and method.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.