Aim To analyse the chemical constituents of the essential oil extracted from the rhizome and root of Notopterygium forbesii Boiss. and provide scientific basis for quality control. Methods The total essential oil was ...Aim To analyse the chemical constituents of the essential oil extracted from the rhizome and root of Notopterygium forbesii Boiss. and provide scientific basis for quality control. Methods The total essential oil was extracted by water-steam distillation and separated by capillary gas chromatography (GC). The components were determined by normalization method, and identified by GC-MS. Results GC-MS exhibited 217 peaks and 100 compounds were identified, accounting for 78.3% of the total essential oil. Conclu...展开更多
Aim To analyse the constituents of the essential oils extracted from the buds of Tussilago farfara L. in the GAP Bases of Traditional Chinese Medical Materials and provide scientific basis for quality control. Methods...Aim To analyse the constituents of the essential oils extracted from the buds of Tussilago farfara L. in the GAP Bases of Traditional Chinese Medical Materials and provide scientific basis for quality control. Methods The essential oils were extracted by water-steam distillation and separated by GC capillary column chromatography. The components were quantitatively determined by normalization, and identified by GC-MS. Results GC-MS exhibited 259 peaks and 65 compounds were identified, accounting for 84.62% of the total essential oil. Conclusion In the total essential oil contained in the buds of Tussilago farfara L., copaene (2.36%), ( + ) -Epi-bicyclosesquiphellandrene ( 3.91% ), γ- elemene (2.18%), fl-bisabolene ( 13.93% ), spathulenol ( 3.44% ) as the sesquiterpenes and its derivatives, and 1-undecene (4.83%), ( E)-cycloundecene (8.49%), bicycle [ 10. 1.0] tridec-l-ene ( 1. 45% ), 1-tridecene (3.44%), (Z)-7,11-dimethyl-3-methylene-1,6,10-dodecatriene (2.66%), 1- pentadecene (4.57%), [ 1R-( 1R^*, 4Z, 9S^* ) ]-4,11,11-trimethyl-8-methylene-bicyclo [ 7.2.0] undec-4-ene ( 1.03% ), 6,6-dimethyl-2-methylene-7-( 3-oxobutylidene )-oxepan-3-ylmethyl acetic acid ester (2.02%), 1, E-11, Z-13-heptadecatriene ( 3.72% ), ( Z, Z, Z) -9,12,15-octadecatrien-l-ol ( 1.85% ), 3,7,11-trimethyl-dodeca-2,4,6,10-tetraenal ( 1.31% ), n-hexadecanoic acid ( 3.12% ) , (Z, Z) -9,12-octadecadienoic acid (2.26%), ( Z, Z, Z) -9,12,15-octadecatrienoic acid methyl ester ( 1.12% ) , heneicosane ( 1.82% ), and pentacosane ( 1.03% ) are the main components.展开更多
Aim To analyse the chemical constituents of the essential oil extracted from the rhizome and root of Notopterygium incisum Ting ex H.T. Chang, providing scientific basis for quality control. Methods The total essentia...Aim To analyse the chemical constituents of the essential oil extracted from the rhizome and root of Notopterygium incisum Ting ex H.T. Chang, providing scientific basis for quality control. Methods The total essential oil was extracted by water-steam distillation and separated by capillary gas chromatography (GC). The components were determined by normalization method, and identified by GC-MS. Results GC-MS exhibited 242 peaks and 83 compounds were identified, accounting for 75.77% of the total essential oil. Conclusion In the total essential oil of the rhizome and root of N. incisum, monoterpenes and sesquiterpenes accounted for 13.63% and 67.93%, respectively, in which ( 1S)-β-pinene ( 1.67% ), 3-carene ( 1.05% ), limonene ( 1.22% ), and 1S-endo-bornyl acetate ( 1.68% ) as the monoterpenes and its derivatives, and ( + ) -β-elemene (6.78%), sativene (1.54%), α-caryophyllene (2.64%), germacrene D (1.67%), eudesma-4 ( 14 ), ll-diene (2.36%), α-selinene (2.42%), δ-cadinene ( 1.55% ), 3,7,11-trimethyl-2,6,10-dodecatrien-1-ol (1.03%), ( + )-elemol (5.18%), (-)-spathulenol (1.40%), guaiol (3.81%), dehydroxy-isocalamendiol ( 1.06% ), γ-eudesmol ( 1.05% ), α-eudesmol (7.97%), bulnesol (3.09%), and carotol (2. 30% ) as the sesquiterpenes and its derivatives were main components. In addition, isopropyl transcinnamate was the maximum compound ( 11.3% ) of the total essential oil.展开更多
Taking low permeability cores of Daqing oilfield for example,the flow characteristics at low velocity were studied with the self-designed micro-flux measuring instrument.Considering the throat distribution and capilla...Taking low permeability cores of Daqing oilfield for example,the flow characteristics at low velocity were studied with the self-designed micro-flux measuring instrument.Considering the throat distribution and capillary model,the thickness of fluid boundary layer under different pressure gradients was calculated,and the mechanism and influencing factors of nonlinear percolation were discussed.The results show that the percolation curve of ultra-low rocks is nonlinear,and apparent permeability is not a constant which increases with pressure gradient.The absorption boundary layer decreases with the increase of pressure gradient,and changes significantly especially in low pressure gradient,which is the essence of nonlinear percolation.The absorption boundary layer is also found to be impacted by the surface property of rocks.展开更多
In the middle of the last century,American scientists put forward the concept of capillary number and obtained the relation curve between capillary number and residual oil through experiments.They revealed that the co...In the middle of the last century,American scientists put forward the concept of capillary number and obtained the relation curve between capillary number and residual oil through experiments.They revealed that the corresponding residual oil saturation decreased with increasing of capillary number;after capillary number reached up to a limit,residual oil saturation would become stable and did not decrease.These important achievements laid a theoretical base for enhanced oil recovery with chemical flooding.On the basis of the theory,scholars developed chemical flooding numerical simulation software UTCHEM.During the numerical simulation study of combination flooding,the authors found that as the capillary number is higher than the limit capillary number,the changes of the residual oil saturation along with the capillary number differ from the classical capillary number curve.Oil displacement experiments prove that there are defects in classic capillary number experimental curve and it is necessary to mend and improve.Capillary number‘calculation’curve is obtained with a method of numerical simulation calculation and a complete description of capillary number curve is provided;On this basis,combination flooding capillary number experimental curve QL is obtained through experiments,which is different from the classical capillary curve;and based on which,an expression of corresponding combination flooding relative permeability curve QL is given and the corresponding relative permeability parameters are determined with experiments.Further oil displacement experiment research recognizes the cause of the singular changes of the capillary number curve."Combination flooding capillary number experimental curve QL"and"combination flooding relative permeability curve QL"are written in combination flooding software IMCFS,providing an effective technical support for the application of combination flooding technical research.展开更多
基金State Projects of the Tenth-Five-Year Plan (No.2001BA701A60-03)
文摘Aim To analyse the chemical constituents of the essential oil extracted from the rhizome and root of Notopterygium forbesii Boiss. and provide scientific basis for quality control. Methods The total essential oil was extracted by water-steam distillation and separated by capillary gas chromatography (GC). The components were determined by normalization method, and identified by GC-MS. Results GC-MS exhibited 217 peaks and 100 compounds were identified, accounting for 78.3% of the total essential oil. Conclu...
文摘Aim To analyse the constituents of the essential oils extracted from the buds of Tussilago farfara L. in the GAP Bases of Traditional Chinese Medical Materials and provide scientific basis for quality control. Methods The essential oils were extracted by water-steam distillation and separated by GC capillary column chromatography. The components were quantitatively determined by normalization, and identified by GC-MS. Results GC-MS exhibited 259 peaks and 65 compounds were identified, accounting for 84.62% of the total essential oil. Conclusion In the total essential oil contained in the buds of Tussilago farfara L., copaene (2.36%), ( + ) -Epi-bicyclosesquiphellandrene ( 3.91% ), γ- elemene (2.18%), fl-bisabolene ( 13.93% ), spathulenol ( 3.44% ) as the sesquiterpenes and its derivatives, and 1-undecene (4.83%), ( E)-cycloundecene (8.49%), bicycle [ 10. 1.0] tridec-l-ene ( 1. 45% ), 1-tridecene (3.44%), (Z)-7,11-dimethyl-3-methylene-1,6,10-dodecatriene (2.66%), 1- pentadecene (4.57%), [ 1R-( 1R^*, 4Z, 9S^* ) ]-4,11,11-trimethyl-8-methylene-bicyclo [ 7.2.0] undec-4-ene ( 1.03% ), 6,6-dimethyl-2-methylene-7-( 3-oxobutylidene )-oxepan-3-ylmethyl acetic acid ester (2.02%), 1, E-11, Z-13-heptadecatriene ( 3.72% ), ( Z, Z, Z) -9,12,15-octadecatrien-l-ol ( 1.85% ), 3,7,11-trimethyl-dodeca-2,4,6,10-tetraenal ( 1.31% ), n-hexadecanoic acid ( 3.12% ) , (Z, Z) -9,12-octadecadienoic acid (2.26%), ( Z, Z, Z) -9,12,15-octadecatrienoic acid methyl ester ( 1.12% ) , heneicosane ( 1.82% ), and pentacosane ( 1.03% ) are the main components.
基金State Projects of the Tenth-Five-Year Plan (No.2001BA701A60-03)
文摘Aim To analyse the chemical constituents of the essential oil extracted from the rhizome and root of Notopterygium incisum Ting ex H.T. Chang, providing scientific basis for quality control. Methods The total essential oil was extracted by water-steam distillation and separated by capillary gas chromatography (GC). The components were determined by normalization method, and identified by GC-MS. Results GC-MS exhibited 242 peaks and 83 compounds were identified, accounting for 75.77% of the total essential oil. Conclusion In the total essential oil of the rhizome and root of N. incisum, monoterpenes and sesquiterpenes accounted for 13.63% and 67.93%, respectively, in which ( 1S)-β-pinene ( 1.67% ), 3-carene ( 1.05% ), limonene ( 1.22% ), and 1S-endo-bornyl acetate ( 1.68% ) as the monoterpenes and its derivatives, and ( + ) -β-elemene (6.78%), sativene (1.54%), α-caryophyllene (2.64%), germacrene D (1.67%), eudesma-4 ( 14 ), ll-diene (2.36%), α-selinene (2.42%), δ-cadinene ( 1.55% ), 3,7,11-trimethyl-2,6,10-dodecatrien-1-ol (1.03%), ( + )-elemol (5.18%), (-)-spathulenol (1.40%), guaiol (3.81%), dehydroxy-isocalamendiol ( 1.06% ), γ-eudesmol ( 1.05% ), α-eudesmol (7.97%), bulnesol (3.09%), and carotol (2. 30% ) as the sesquiterpenes and its derivatives were main components. In addition, isopropyl transcinnamate was the maximum compound ( 11.3% ) of the total essential oil.
基金Project(2008ZX05013) supported by the National Science and Technology Project of ChinaProject(10672187) supported by the National Natural Science Foundation of China
文摘Taking low permeability cores of Daqing oilfield for example,the flow characteristics at low velocity were studied with the self-designed micro-flux measuring instrument.Considering the throat distribution and capillary model,the thickness of fluid boundary layer under different pressure gradients was calculated,and the mechanism and influencing factors of nonlinear percolation were discussed.The results show that the percolation curve of ultra-low rocks is nonlinear,and apparent permeability is not a constant which increases with pressure gradient.The absorption boundary layer decreases with the increase of pressure gradient,and changes significantly especially in low pressure gradient,which is the essence of nonlinear percolation.The absorption boundary layer is also found to be impacted by the surface property of rocks.
文摘In the middle of the last century,American scientists put forward the concept of capillary number and obtained the relation curve between capillary number and residual oil through experiments.They revealed that the corresponding residual oil saturation decreased with increasing of capillary number;after capillary number reached up to a limit,residual oil saturation would become stable and did not decrease.These important achievements laid a theoretical base for enhanced oil recovery with chemical flooding.On the basis of the theory,scholars developed chemical flooding numerical simulation software UTCHEM.During the numerical simulation study of combination flooding,the authors found that as the capillary number is higher than the limit capillary number,the changes of the residual oil saturation along with the capillary number differ from the classical capillary number curve.Oil displacement experiments prove that there are defects in classic capillary number experimental curve and it is necessary to mend and improve.Capillary number‘calculation’curve is obtained with a method of numerical simulation calculation and a complete description of capillary number curve is provided;On this basis,combination flooding capillary number experimental curve QL is obtained through experiments,which is different from the classical capillary curve;and based on which,an expression of corresponding combination flooding relative permeability curve QL is given and the corresponding relative permeability parameters are determined with experiments.Further oil displacement experiment research recognizes the cause of the singular changes of the capillary number curve."Combination flooding capillary number experimental curve QL"and"combination flooding relative permeability curve QL"are written in combination flooding software IMCFS,providing an effective technical support for the application of combination flooding technical research.
