Hydrocarbon separation and analysis apparatus and methods
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
C10G-053/08
C10G-025/00
B01D-015/26
C10G-025/12
G01N-030/46
G01N-033/28
B01J-020/281
B01J-020/283
B01J-020/284
B01J-020/286
B01J-020/287
B01D-015/00
G01N-030/08
G01N-030/88
출원번호
US-0237568
(2011-09-20)
등록번호
US-9353317
(2016-05-31)
발명자
/ 주소
Schabron, John F.
Boysen, Ryan B.
Kalberer, Eric W.
Rovani, Jr., Joseph F.
출원인 / 주소
The University of Wyoming Research Corporation
대리인 / 주소
Santangelo Law Offices, P.C.
인용정보
피인용 횟수 :
3인용 특허 :
14
초록▼
The inventive technology may involve, in particular embodiments, novel use of a non-porous, high surface energy stationary phase to adsorb, in reversible fashion, the most polar component of a resins fraction of an input hydrocarbon when a mobile phase is passed over the stationary phase. Such rever
The inventive technology may involve, in particular embodiments, novel use of a non-porous, high surface energy stationary phase to adsorb, in reversible fashion, the most polar component of a resins fraction of an input hydrocarbon when a mobile phase is passed over the stationary phase. Such reversible adsorption prevents irreversibly adsorption of such components on active stationary phase(s) downflow of the non-porous, high surface energy stationary phase, thereby conserving stationary phase costs and increasing resolution of resins elutions, and accuracy of hydrocarbon component results. Aspects of the inventive technology may also involve a novel combination of a solubility based asphaltene component fractionating and analysis method and an adsorption chromatography method for separating and/or analyzing saturate, aromatics and resins components of an input hydrocarbon.
대표청구항▼
1. A method comprising the steps of: establishing a hydrocarbon into and as part of a first solvent mobile phase, said hydrocarbon including saturates, asphaltenes, a resins fraction that includes highly polar aromatic components and additional resins components, and an aromatics fraction that inclu
1. A method comprising the steps of: establishing a hydrocarbon into and as part of a first solvent mobile phase, said hydrocarbon including saturates, asphaltenes, a resins fraction that includes highly polar aromatic components and additional resins components, and an aromatics fraction that includes aromatics that are not highly polar;passing said first solvent mobile phase over an inert stationary phase;precipitating substantially all of said asphaltenes within said inert stationary phase to generate precipitated asphaltenes;subsequently passing said first solvent mobile phase over a non-porous, high surface energy, adsorptive stationary phase to reversibly adsorb substantially all of said highly polar aromatic components of said resins fraction from said first solvent mobile phase onto said non-porous, high surface energy, adsorptive stationary phase, thereby preventing irreversible adsorption of said substantially all of said highly polar aromatic components onto a porous, active stationary phase established downflow of said non-porous, high surface energy, adsorptive stationary phase;subsequently passing said first solvent mobile phase over said porous, active stationary phase;reversibly adsorbing substantially all of said aromatics fraction onto said porous, active stationary phase;eluting substantially all of said saturates;passing an asphaltene solvent over said inert stationary phase; andeluting at least a portion of said asphaltenes,wherein said first solvent mobile phase is without said precipitated asphaltenes during performance of said step of subsequently passing said first solvent mobile phase over a non-porous, high surface energy, adsorptive stationary phase. 2. A method as described in claim 1 wherein said highly polar aromatic components of said resins fraction comprise highly pericondensed resins materials. 3. A method as described in claim 1 wherein said step of subsequently passing said first solvent mobile phase over a non-porous, high surface energy, adsorptive stationary phase comprises the step of passing said first solvent mobile phase over glass beads. 4. A method as described in claim 1 wherein said step of subsequently passing said first solvent mobile phase over a non-porous, high surface energy, adsorptive stationary phase comprises the step of passing said first solvent mobile phase over ceramics. 5. A method as described in claim 1 wherein said step of subsequently passing said first solvent mobile phase over a non-porous, high surface energy, adsorptive stationary phase comprises the step of passing said first solvent mobile phase over metal. 6. A method as described in claim 1 wherein said step of subsequently passing said first solvent mobile phase over said porous, active stationary phase comprises the step of passing said first solvent mobile phase over a weakly adsorbing stationary phase. 7. A method as described in claim 6 wherein said weakly adsorbing stationary phase comprises activity reduced silica. 8. A method as described in claim 6 wherein said weakly adsorbing stationary phase comprises an amino functional group bonded to silica matrix. 9. A method as described in claim 6 wherein said weakly adsorbing stationary phase comprises a cyano functional group bonded to silica matrix. 10. A method as described in claim 6 wherein said step of subsequently passing said first solvent mobile phase over said porous, active stationary phase comprises the step of passing said first solvent mobile phase over a highly active stationary phase. 11. A method as described in claim 1 wherein said step of passing said first solvent mobile phase over an inert stationary phase comprises the step of passing an aliphatic solvent mobile phase over an inert stationary phase. 12. A method as described in claim 1 wherein said step of passing said first solvent mobile phase over an inert stationary phase comprises the step of passing a low polarity solvent mobile phase over an inert stationary phase. 13. A method as described in claim 12 wherein said low polarity solvent comprises heptane. 14. A method as described in claim 12 wherein said low polarity solvent comprises a solvent selected from the group consisting of: pentane, hexane, heptane and iso-octane. 15. A method as described in claim 1 wherein said first solvent mobile phase comprises a solvent selected from the group consisting of hexane, isooctane, and trimethylpentane. 16. A method as described in claim 1 wherein said first solvent mobile phase is a low polarity solvent mobile phase. 17. A method as described in claim 1 wherein said step of establishing a hydrocarbon into and as part of a first solvent mobile phase comprises the step of establishing a bitumen in solvent solution into said first solvent mobile phase. 18. A method as described in claim 17 wherein said step of establishing a bitumen in solvent solution into and as part of said first solvent mobile phase comprises the step of establishing a bitumen in a solvent that is strong enough to keep asphaltenes in solution and dissolve said bitumen. 19. A method as described in claim 1 wherein said step of establishing a hydrocarbon into and as part of a first solvent mobile phase comprises the step of establishing a crude oil in solvent solution into and as part of said first solvent mobile phase. 20. A method as described in claim 1 wherein said step of establishing a hydrocarbon into and as part of a first solvent mobile phase comprises the step of establishing a heavy oil in solvent solution into and as part of said first solvent mobile phase. 21. A method as described in claim 1 wherein said step of establishing a hydrocarbon into and as part of a first solvent mobile phase comprises the step of establishing an opportunity crude oil in solvent solution into and as part of said first solvent mobile phase. 22. A method as described in claim 1 wherein said step of establishing a hydrocarbon into and as part of a first solvent mobile phase comprises the step of establishing a hydrocarbon in solvent solution into and as part of said first solvent mobile phase. 23. A method as described in claim 22 wherein said step of establishing a hydrocarbon in solvent solution into and as part of said first solvent mobile phase comprises the step of establishing a hydrocarbon in a strong solvent into and as part of said first solvent mobile phase. 24. A method as described in claim 22 wherein said step of establishing a hydrocarbon in solvent solution into and as part of said first solvent mobile phase comprises the step of establishing a hydrocarbon in solvent solution selected from the group consisting of: hydrocarbon in toluene solution, hydrocarbon in chlorobenzene solution, hydrocarbon in dichloromethane solution, hydrocarbon in benzene solution, hydrocarbon in toluene solution, hydrocarbon in xylene solution, hydrocarbon in methyl naphthalene solution, hydrocarbon in n-methyl pyrrolidone solution, hydrocarbon in cyclyhexanone solution, hydrocarbon in chloroform solution, hydrocarbon in trichloroethylene solution, hydrocarbon in tetrachloroethylene solution, hydrocarbon in methylene chloride solution, hydrocarbon in chlorobenzene solution, hydrocarbon substance in carbon disulfide solution, hydrocarbon substance in cyclohexane solution, hydrocarbon in quinoline solution, hydrocarbon in pyridine solution, and hydrocarbon in decalin solution. 25. A method as described in claim 1 wherein said step of establishing a hydrocarbon into and as part of a first solvent mobile phase comprises the step of establishing a viscous hydrocarbon in solvent solution into and as part of said first solvent mobile phase. 26. A method as described in claim 25 wherein step of establishing a viscous hydrocarbon in solvent solution into and as part of said first solvent mobile phase comprises the step of establishing a crude oil in solvent solution into and as part of said first solvent mobile phase. 27. A method as described in claim 1 wherein said step of establishing a hydrocarbon into and as part of a solvent mobile phase comprises the step of establishing an undiluted, light oil into and as part of said solvent mobile phase. 28. A method as described in claim 1 wherein said step of passing said first solvent mobile phase over an inert stationary phase comprises the step of passing said first solvent mobile phase over polytetrafluoroethylene. 29. A method as described in claim 1 wherein said step of subsequently passing said first solvent mobile phase over a porous, active stationary phase comprises the step of passing said first solvent mobile phase over a highly active stationary phase. 30. A method as described in claim 1 wherein said step of subsequently passing said first solvent mobile phase over a porous active stationary phase comprises the step of passing said first solvent mobile phase over an activity enhanced silica stationary phase. 31. A method as described in claim 1 wherein said step of subsequently passing said first solvent mobile phase over a porous active stationary phase comprises the step of passing said first solvent mobile phase over an activity enhanced alumina stationary phase. 32. A method as described in claim 1 wherein said steps are performed in the order in which they appear. 33. A method as described in claim 1 wherein said step of eluting saturates comprises the step of eluting aliphatic hydrocarbons. 34. A method as described in claim 1 further comprising the step of analyzing said saturates. 35. A method as described in claim 1 further comprising the step of flowing an aromatic desorbing mobile phase over said porous, active stationary phase, said aromatic desorbing mobile phase able to desorb said aromatics fraction from said porous, active stationary phase. 36. A method as described in claim 35 further comprising the step of desorbing said aromatics fraction. 37. A method as described in claim 35 wherein said step of flowing an aromatic desorbing mobile phase over said porous, active stationary phase comprises the step of flowing toluene over said porous, active stationary phase. 38. A method as described in claim 35 wherein said step of flowing an aromatic desorbing mobile phase over said porous, active stationary phase comprises the step of backflowing said aromatic desorbing mobile phase over said porous, active stationary phase. 39. A method as described in claim 35 wherein said step of flowing an aromatic desorbing mobile phase over said porous, active stationary phase comprises the step of flowing said aromatic desorbing mobile phase over a weakly adsorbing stationary phase. 40. A method as described in claim 39 wherein said step of flowing said aromatic desorbing mobile phase over said weakly adsorbing stationary phase comprises the step of backflowing said aromatic desorbing mobile phase over said weakly adsorbing stationary phase. 41. A method as described in claim 35 wherein said step of flowing an aromatic desorbing mobile phase over said porous, active stationary phase comprises the step of using at least one flow control valve. 42. A method as described in claim 1 further comprising the step of flowing an aromatics desorbing mobile phase over said porous, active stationary phase but not over said non-porous, high surface energy, adsorptive stationary phase. 43. A method as described in claim 42 wherein said step of flowing an aromatics desorbing mobile phase over said porous, active stationary phase but not over said non-porous, high surface energy, adsorptive stationary phase comprises the step of using at least one flow control valve to backflow said aromatics desorbing mobile phase over said porous, active stationary phase. 44. A method as described in claim 42 wherein said step of flowing an aromatics desorbing mobile phase over said porous, active stationary phase comprises the step of flowing said aromatics desorbing mobile phase over a weakly adsorbing stationary phase. 45. A method as described in claim 44 wherein said step of flowing said aromatics desorbing mobile phase over said weakly adsorbing stationary phase comprises the step of backflowing said aromatics desorbing mobile phase over said weakly adsorbing stationary phase. 46. A method as described in claim 42 wherein said step of flowing an aromatics desorbing mobile phase over said porous, active stationary phase but not over said non-porous, high surface energy, adsorptive stationary phase comprises the step of using at least one flow control valve. 47. A method as described in claim 46 wherein said step of step of using at least one flow control valve comprises the step of using at least solvent switching or flow switching valves. 48. A method as described in claim 42 further comprising the step of eluting substantially all of said aromatics fraction. 49. A method as described in claim 48 further comprising the step of analyzing said aromatics fraction. 50. A method as described in claim 1 further comprising the step of flowing a resins material desorbing mobile phase over said non-porous, high surface energy, adsorptive stationary phase, said resins material desorbing mobile phase able to desorb resins adsorbed onto said non-porous, high surface energy, adsorptive stationary phase. 51. A method as described in claim 50 wherein said step of flowing a resins desorbing mobile phase over said non-porous, high surface energy, adsorptive stationary phase comprises the step of flowing said resins desorbing mobile phase over said non-porous, high surface energy, adsorptive stationary phase but not over said porous, active stationary phase. 52. A method as described in claim 51 wherein said step of flowing a resins desorbing mobile phase over said non-porous, high surface energy, adsorptive stationary phase but not over said active stationary phase comprises the step of backflowing said resins desorbing mobile phase over said non-porous, high surface energy, adsorptive stationary phase. 53. A method as described in claim 50 wherein said step of flowing a resins desorbing mobile phase over said non-porous, high surface energy, adsorptive stationary phase comprises the step of flowing CH2Cl2:MeOH over said non-porous, high surface energy, adsorptive stationary phase. 54. A method as described in claim 50 further comprising the step of flowing said resins desorbing mobile phase over a weakly adsorbing stationary phase. 55. A method as described in claim 54 further comprising the step of desorbing resins adsorbed onto said weakly adsorbing stationary phase. 56. A method as described in claim 50 further comprising the step of desorbing said resins adsorbed onto said non-porous, high surface energy, adsorptive stationary phase. 57. A method as described in claim 56 further comprising the step of analyzing said resins desorbed from said non-porous, high surface energy, adsorptive stationary phase. 58. A method as described in claim 50 wherein said step of further comprising the step of flowing said resins desorbing mobile phase over an activity reduced stationary phase but not over a highly active stationary phase. 59. A method as described in claim 58 further comprising the step of desorbing resins adsorbed onto said activity reduced stationary phase. 60. A method as described in claim 59 further comprising the step of eluting said resins. 61. A method as described in claim 59 further comprising the step of analyzing said resins. 62. A method as described in claim 1 wherein said step of passing an asphaltene solvent over said inert stationary phase comprises the step of passing a first asphaltene solvent over said inert stationary phase, thereby dissolving at least a first portion of said precipitated asphaltenes. 63. A method as described in claim 62 wherein said step of dissolving at least a first portion of said precipitated asphaltenes comprises the step of dissolving a highly alkyl substituted pericondensed aromatic material fraction. 64. A method as described in claim 63 further comprising the step of analyzing said highly alkyl substituted pericondensed aromatic material fraction. 65. A method as described in claim 62 wherein said step of dissolving at least a first portion of said precipitated asphaltenes precipitated within said inert stationary phase with a first asphaltene solvent comprises the step of dissolving at least a first portion of said asphaltenes with cyclohexane. 66. A method as described in claim 62 further comprising the step of dissolving at least a second portion of said precipitated asphaltenes with a second asphaltene solvent, said second asphaltene solvent being stronger than said first asphaltene solvent. 67. A method as described in claim 66 wherein said step of dissolving at least a second portion of said precipitated asphaltenes comprises the step of dissolving a pericondensed aromatic material fraction. 68. A method as described in claim 67 further comprising the step of analyzing said pericondensed aromatic material fraction. 69. A method as described in claim 66 wherein said step of dissolving at least a second portion of said precipitated asphaltenes with a second asphaltene solvent comprises the step of dissolving at least a second portion of said precipitated asphaltenes with toluene. 70. A method as described in claim 66 further comprising the step of dissolving at least a third portion of said precipitated asphaltenes with a third asphaltene solvent, said third solvent stronger than said second asphaltene solvent. 71. A method as described in claim 70 wherein said step of dissolving at least a third portion of said precipitated asphaltenes comprises the step of dissolving a pre-coke aromatic material fraction. 72. A method as described in claim 71 further comprising the step of analyzing said pre-coke aromatic fraction. 73. A method as described in claim 70 wherein said step of dissolving at least a third portion of said precipitated asphaltenes with a third asphaltent solvent comprises the step of dissolving at least a third portion of said asphaltenes with methylene chloride:methanol. 74. A method as described in claim 62 further comprising the step of flowing an aromatic desorbing mobile phase over said porous, active stationary phase. 75. A method as described in claim 74 wherein said step of passing a first asphaltene solvent over said inert stationary phase is performed before said step of flowing an aromatic desorbing mobile phase over said porous, active stationary phase is performed. 76. A method as described in claim 1 further comprising the step of flushing said stationary phases and system components with at least one solvent. 77. A method as described in claim 76 wherein said step of flushing said stationary phases and system components comprises the step of flushing with toluene and heptane. 78. A method as described in claim 1 wherein said method is a method selected from the group consisting of coking onset estimation method, oil processing method; oil fractionating method, oil production method, pipeline fouling related method, hydrotreating method, distillation method, vacuum distillation method, atmospheric distillation method, visbreaking method, blending method, asphalt formation method, asphalt extraction method, and asphaltene content of oil measurement method. 79. A method as described in claim 1 wherein said step of eluting saturates is performed before said step of eluting at least a portion of said precipitated asphaltenes is performed. 80. A method as described in claim 1 wherein said step of eluting at least a portion of said precipitated asphaltenes is performed before said step of eluting saturates is performed. 81. A method as described in claim 1 wherein substantially all of said additional resins components are reversibly adsorbed onto said non-porous, high surface energy, adsorptive stationary phase. 82. A method as described in claim 1 wherein said porous, active stationary phase comprises an activity reduced stationary phase. 83. A method as described in claim 82 wherein said activity reduced stationary phase adsorbs at least a portion of said additional resins components. 84. A method as described in claim 82 wherein said porous, active stationary phase further comprises a highly active stationary phase. 85. A method as described in claim 84 further comprising the step of flowing a resins desorbing mobile phase over said activity reduced stationary phase but not over said highly active stationary phase. 86. A method as described in claim 1 wherein said step of subsequently passing said first solvent mobile phase over said porous, active stationary phase comprises the step of passing said first solvent mobile phase over a highly active stationary phase. 87. A method as described in claim 86 wherein said step of subsequently passing said first solvent mobile phase over said porous, active stationary phase further comprises the step of passing said first solvent mobile phase over an activity reduced stationary phase, wherein each of said active stationary phases is established in a different column. 88. A method as described in claim 1 wherein said step of establishing a hydrocarbon into and as part of a first solvent mobile phase comprises establishing a hydrocarbon and additive or rejuvenator into and as part of said first solvent mobile phase. 89. A method as described in claim 1 further comprising the step of passing said first solvent mobile phase over a weakly adsorbing stationary phase established downflow of said non-porous, high surface energy, adsorptive stationary phase. 90. A method as described in claim 89 wherein said step of passing said first solvent mobile phase over a weakly adsorbing stationary phase comprises the step of passing said solvent mobile phase over a weakly adsorbing stationary phase established upflow of said porous, active stationary phase. 91. A method as described in claim 89 wherein said weakly adsorbing stationary phase comprises activity reduced silica. 92. A method as described in claim 89 wherein said weakly adsorbing stationary phase comprises a functional group bonded to silica matrix. 93. A method as described in claim 92 wherein said weakly adsorbing stationary phase comprises an amino functional group bonded to silica matrix. 94. A method as described in claim 92 wherein said weakly adsorbing stationary phase comprises a cyano functional group bonded to silica matrix. 95. A method as described in claim 1 wherein said step of passing said first solvent mobile phase over an inert stationary phase comprises the step of passing said first solvent mobile phase over a substantially inert stationary phase. 96. A method as described in claim 1 wherein said irreversible adsorption of said substantially all of said highly polar aromatic components onto a porous, active stationary phase established downflow of said non-porous, high surface energy, adsorptive stationary phase comprises adsorption of said substantially all of said highly polar aromatic components, where, for said components to be desorbed from said porous, active stationary phase, a solvent that would substantially inactivate said porous, active stationary phase is required. 97. A method as described in claim 1 wherein said irreversible adsorption of said substantially all of said highly polar aromatic components onto a porous, active stationary phase established downflow of said non-porous, high surface energy, adsorptive stationary phase comprises adsorption of materials where solvents cannot desorb all adsorbed components from said porous, active stationary phase.
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