TARGET-BASED METHOD FOR HIGH-THROUGHPUT AND SUBCLASS SPECIFIC IgG GLYCAN PROFILING IN HUMAN PLASMA
US-2024353417-A1 · Oct 24, 2024 · US
Petroleum-fluid property prediction from gas chromatographic analysis of rock extracts or fluid samples
US10641750B2 · US · B2
| Field | Value |
|---|---|
| Publication number | US-10641750-B2 |
| Application number | US-201313957911-A |
| Country | US |
| Kind code | B2 |
| Filing date | Aug 2, 2013 |
| Priority date | Aug 3, 2012 |
| Publication date | May 5, 2020 |
| Grant date | May 5, 2020 |
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- Title
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- Abstract
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- First independent claim
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Abstract
Official abstract text for this publication.
This method allows for prediction of subsurface fluid properties (e.g., phase or API gravity) using gas chromatogram data of a small-volume extract. Small volume equates to microliter scale volume (or milligram scale weight) from a subsurface rock sample, where a fluid test may not be available for analysis. The method may also be applied to petroleum liquid samples where drilling fluid or other contaminants preclude accurate direct property measurement. Gas chromatographic data is calibrated to measured petroleum properties; preferably local oils from the same petroleum system, however, a general global calibration can also be used.
First claim
Opening claim text (preview).
The invention claimed is: 1. A method of analyzing a reservoir fluid property of a small volume rock extract or fluid sample, comprising: a) obtaining a rock extract or fluid sample from a subterranean reservoir, wherein a volume of the rock extract or fluid sample is in the microliter range; b) analyzing the rock extract or fluid sample by gas chromatography to provide a gas chromatogram; c) calculating chromatographic peak area for three or more alkanes in the gas chromatogram; d) selecting a representative series of three or more alkane peaks for analysis; e) optionally, normalizing the alkane peak areas across the representative series; f) optionally, converting the chromatographic peak areas of the selected series to mole percent or weight percent; g) obtaining a plot of the concentration in terms of peak area, mole percent or weight percent, against carbon number or molecular weight; h) fitting an equation to plotted concentrations obtained from (g); i) determining goodness of fit (R 2 ) for the equation to the plotted peaks; j) re-selecting the representative series of alkane peaks and repeating (e), (f), (g), (h), (i) and (j), k) identifying calibration petroleum sample or samples with similar plot; l) assigning one or more fluid properties from the calibration petroleum sample or samples to the rock extract or fluid sample with unknown property; m) determining the unknown property of the rock extract or fluid sample based on the assigning; and n) adjusting a field development operation based on the unknown property determined in step m). 2. The method of claim 1 , wherein the peak area in step (g) is normalized. 3. The method of claim 1 , wherein the mole percent or weight percent in step (g) is normalized. 4. The method of claim 1 , wherein said selected representative series of alkanes or pseudocomponents comprises peaks or areas between C 10 and C 35 . 5. The method of claim 1 , wherein said representative series of alkanes or pseudocomponents comprises peaks or areas corresponding to an alkane molecular weight of approximately C 8 -C 12 , C 10 -C 14 , C 10 -C 15 , C 10 -C 16 , C 10 -C 17 , C 10 -C 18 , C 10 -C 19 , C 10 -C 20 , C 10 -C 21 , C 10 -C 22 , C 10 -C 23 , C 10 -C 24 , C 10 -C 25 , C 10 -C 26 , C 10 -C 27 , C 10 -C 30 , C 10 -C 32 , C 10 -C 34 , C 10 -C 36 , C 10 -C 37 , C 12 -C 14 , C 12 -C 15 , C 12 -C 16 , C 12 -C 17 , C 12 -C 18 , C 12 -C 19 , C 12 -C 20 , C 12 -C 21 , C 12 -C 22 , C 12 -C 23 , C 12 -C 24 , C 12 -C 25 , C 12 -C 26 , C 12 -C 27 , C 12 -C 30 , C 12 -C 32 , C 12 -C 34 , C 12 -C 36 , C 12 -C 37 , C 14 -C 16 , C 14 -C 17 , C 14 -C 18 , C 14 -C 19 , C 14 -C 20 , C 14 -C 21 , C 14 -C 22 , C 14 -C 23 , C 14 -C 24 , C 14 -C 25 , C 14 -C 26 , C 14 -C 27 , C 14 -C 30 , C 14 -C 32 , C 14 -C 34 , C 14 -C 36 , C 14 -C 37 C 15 -C 17 , C 15 -C 18 , C 15 -C 19 , C 15 -C 20 , C 15 -C 21 , C 15 -C 22 , C 15 - C 23 , C 15 -C 24 , C 15 -C 25 , C 15 -C 26 , C 15 -C 27 , C 15 -C 30 , C 15 -C 32 , C 15 -C 34 , C 15 -C 36 , C 15 -C 37 , C 17 -C 19 , C 17 -C 20 , C 17 -C 21 , C 17 -C 22 , C 17 -C 23 , C 17 -C 24 , C 17 -C 25 , C 17 -C 26 , C 17 -C 27 , C 17 -C 30 , C 17 -C 32 , C 17 -C 34 , C 17 -C 36 , C 17 -C 37 , C 21 -C 16 , C 21 -C 18 , C 21 -C 19 , C 21 -C 23 , C 21 -C 24 , C 21 -C 25 , C 21 -C 26 , C 21 -C 27 , C 21 -C 30 , C 21 -C 32 , C 21 -C 34 , C 21 -C 36 , C 21 -C 37 , C 22 -C 16 , C 22 -C 18 , C 22 -C 19 , C 22 -C 20 , C 22 -C 24 , C 22 -C 25 , C 22 -C 26 , C 22 -C 27 , C 22 -C 30 , C 22 -C 32 , C 22 -C 34 , C 22 -C 36 , C 22 -C 37 , C 23 -C 16 , C 23 -C 18 , C 23 -C 19 , C 23 -C 20 , C 23 -C 25 , C 23 -C 26 , C 23 -C 27 , C 23 -C 30 , C 23 -C 32 , C 23 -C 34 , C 23 -C 36 , C 23 -C 37 , and any combination thereof. 6. The method of claim 1 , wherein a chromatographic spectra is stored in a non-transitory computer medium utilizing column separated value, tab separated value, hypertext machine language, relational database, text or other format of storing chromatographic spectra. 7. A method of analyzing a reservoir fluid property of a small volume rock extract or fluid sample, comprising: a) obtaining a rock extract or fluid sample from a subterranean reservoir, wherein a volume of the rock extract or fluid sample is in the microliter range; b) analyzing the rock extract or fluid sample by gas chromatography to provide a gas chromatogram; c) calculating chromatographic area for three or more alkane pseudocomponents in the gas chromatogram; d) selecting a representative series of three or more pseudocomponent areas for analysis; e) optionally, normalizing the pseudocomponent peak areas across the representative series; f) optionally, converting the pseudocomponent peak areas of the selected series to mole percent or weight percent; g) obtaining a plot of the concentration in terms of pseudocomponent peak area, mole percent or weight percent against carbon number or molecular weight; h) fitting an equation to plotted concentrations obtained from (g); i) determining goodness of fit (R 2 ) for the equation to the pseudocomponent areas; j) re-selecting the representative series of pseudocomponent areas and repeating (e), (f), (g), (h), (i) and (j) as needed to obtain suitable goodness of fit; k) identifying a calibration petroleum sample with a similar plot; l) assigning one or more fluid properties selected from the group consisting of API gravity, fluid phase, and any combination thereof, from the calibration petroleum sample to the rock extract or fluid sample with unknown properties; m) determining petroleum API gravity or petroleum phase of the rock extract or fluid sample based on the assigning; and n) adjusting a field development operation based on the petroleum API gravity or petroleum phase of the rock extract or fluid sample determined in step m). 8. The method of claim 7 , wherein the peak area in step (g) is normalized. 9. The method of claim 7 , wherein the mole percent or weight percent in step (g) is normalized. 10. The method of claim 7 , wherein said representative series of alkanes or pseudocomponents comprises peaks or areas between C 10 and C 35 . 11. The method of claim 7 , wherein said representative series of alkanes or pseudocomponents comprises peaks or areas corresponding to an alkane molecular weight of approximately C 8 -C 12 , C 10 -C 15 , C 10 -C 16 , C 10 -C 17 , C 10 -C 18 , C 10 -C 19 , C 10 -C 20 , C 10 -C 21 , C 10 -C 22 , C 10 -C 23 , C 10 -C 24 , C 10 -C 25 , C 10 -C 26 , C 10 -C 27 , C 10 -C 30 , C 10 -C 32 , C 10 -C 34 , C 10 -C 36 , C 10 -C 37 , C 12 -C 14 , C 12 -C 15 , C 12 -C 16 , C 12 -C 17 , C 12 -C 18 , C 12 -C 19 , C 12 -C 20 , C 12 -C 21 , C 12 -C 22 , C 12 -C 23 , C 12 -C 24 , C 12 -C 25 , C 12 -C 26 , C 12 -C 27 , C 12 -C 30 , C 12 -C 32 , C 12 -C 34 , C 12 -C 36 , C 12 -C 37 , C 14 -C 16 , C 14 -C 17 , C 14 -C 18 , C 14 -C 19 , C 14 -C 20 , C 14 -C 21 , C 14 -C 22 , C 14 -C 23 , C 14 -C 24 , C 14 -C 25 , C 14 -C 26 , C 14 -C 27 , C 14 -C 30 , C 14 -C 32 , C 14 -C 34 , C 14 -C 36 , C 14 -C 37 C 15 -C 17 , C 15 -C 18 , C 15 -C 19 , C 15 -C 20 , C 15 -C 21 , C 15 -C 22 , C 15 -C 23 , C 15 - C 24 , C 15 -C 25 , C 15 -C 26 , C 15 -C 27 , C 15 -C 30 , C 15 -C 32 , C 15 -C 34 , C 15 -C 36 , C 15 -C 37 , C 17 -C 19 , C 17 -C 20 , C 17 -C 21 , C 17 -C 22 , C 17 -C 23 , C 17 -C 24 , C 17 -C 25 , C 17 -C 26 , C 17 -C 27 , C 17 -C 30 , C 17 -C 32 , C 17 -C 34 , C 17 -C 36 , C 17 -C 37 , C 21 -C 16 , C 21 -C 18 , C 21 -C 19 , C 21 -C 23 , C 21 -C 24 , C 21 -C 25 , C 21 -C 26 , C 21 -C 27 , C 21 -C 30 , C 21 -C 32 , C 21 -C 34 , C 21 -C 36 , C 21 -C 37 , C 22 -C 16 , C 22 -C 18 , C 22 -C 19 , C 22 -C 20 , C 22 -C 24 , C 22 -C 25 , C 22 -C 26 , C 22 -C 27 , C 22 -C 30 , C 22 -C 32 , C 22 -C 34 , C 22 -C 36 ,
Assignees
Inventors
Classifications
Group type analysis, e.g. of components having structural properties in common · CPC title
Raw oil, drilling fluid or polyphasic mixtures · CPC title
- G01N30/88Primary
Integrated analysis systems specially adapted therefor, not covered by a single one of the groups G01N30/04 - G01N30/86 · CPC title
involving hydrocarbons · CPC title
Recording, data aquisition, archiving and storage · CPC title
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Frequently asked questions
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- What does patent US10641750B2 cover?
- This method allows for prediction of subsurface fluid properties (e.g., phase or API gravity) using gas chromatogram data of a small-volume extract. Small volume equates to microliter scale volume (or milligram scale weight) from a subsurface rock sample, where a fluid test may not be available for analysis. The method may also be applied to petroleum liquid samples where drilling fluid or othe…
- Who is the assignee on this patent?
- Conocophillips Co
- What technology area does this patent fall under?
- Primary CPC classification G01N30/88. Mapped technology areas include Physics.
- When was this patent published?
- Publication date Tue May 05 2020 00:00:00 GMT+0000 (Coordinated Universal Time) (B2). Legal status and post-grant events are not shown on this page.
- What related patents are in patentsdb?
- We list 8 related publications on this page (citations in our corpus or others sharing the same primary CPC).