IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0614829
(2009-11-09)
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등록번호 |
US-8176984
(2012-05-15)
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발명자
/ 주소 |
- Ramakrishnan, Terizhandur S.
- de Loubens, Romain
- Altundas, Yusuf Bilgin
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출원인 / 주소 |
- Schlumberger Technology Corporation
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인용정보 |
피인용 횟수 :
0 인용 특허 :
3 |
초록
▼
Carbon dioxide is sequestered in a formation using dual or multiple completion and injection methods that reduce or eliminates upward leak rates of the sequestered carbon dioxide. The dual or multiple completion and injection method involves the injection of a benign fluid such as brine (water) into
Carbon dioxide is sequestered in a formation using dual or multiple completion and injection methods that reduce or eliminates upward leak rates of the sequestered carbon dioxide. The dual or multiple completion and injection method involves the injection of a benign fluid such as brine (water) into a permeable layer of the formation located above the sequestration layer and which is separated form the sequestration layer by a nearly impermeable layer. The water is injected at the same time the carbon dioxide is injected.
대표청구항
▼
1. A method for sequestration of carbon dioxide in a formation traversed by a cased wellbore, comprising: a) finding a location in the formation having a first permeable layer directly overlain by a nearly impermeable layer, which in turn is overlain by a second permeable layer;b) running simulation
1. A method for sequestration of carbon dioxide in a formation traversed by a cased wellbore, comprising: a) finding a location in the formation having a first permeable layer directly overlain by a nearly impermeable layer, which in turn is overlain by a second permeable layer;b) running simulations of the formation assuming injection of carbon dioxide into the first permeable layer and injection of water along at least one length in said second permeable layer in order to find at least one length which provides desired results concerning leakage of carbon dioxide from the first permeable layer;c) completing the wellbore with at least two completions and with first perforations in the casing along said first permeable layer for the purpose of injecting carbon dioxide into the first permeable layer and with at least one set of second perforations in the casing along said at least one length which provides desired results for the purpose of injecting water into the second permeable layer; andd) injecting carbon dioxide and water into their respective layers simultaneously, with the nearly impermeable layer therebetween, where the water is injected at a pressure at least equal to the carbon dioxide injection pressure plus a gravitational head correction for the water and carbon dioxide minus an entry capillary pressure of the nearly impermeable layer. 2. A method according to claim 1, wherein: said at least two completions comprises at least three completions, and said at least one set of second perforations in the casing along said at least one length comprises at least a first set and a second set of second perforations. 3. A method according to claim 2, further comprising: locating a first pressure sensor along said formation which senses pressure in said first permeable layer;locating a second pressure sensor along said formation which senses pressure at a first location in said second permeable layer; andlocating a third pressure sensor along said formation which senses pressure at a second location in said second permeable layer. 4. A method according to claim 3, wherein: said first pressure sensor is located along said first permeable layer adjacent said impermeable layer, andsaid second pressure sensor is located along said second permeable layer adjacent said impermeable layer. 5. A method according to claim 4, wherein: said third pressure sensor is located along said second permeable layer distant said impermeable layer. 6. A method according to claim 3, further comprising: using a feedback control algorithm which utilizes readings of said first pressure sensor, said second pressure sensor, and said third pressure sensor, controlling and changing over time a first water injection pressure at which water is injected into said second permeable layer through said two sets of second perforations. 7. A method according to claim 1, further comprising: locating a first pressure sensor in said formation which senses pressure in said first permeable layer;locating a second pressure sensor in said formation which senses pressure at a first location in said second permeable layer;locating a third pressure sensor in said formation which senses pressure at a second location in said second permeable layer; andusing a feedback control algorithm which utilizes readings of said first pressure sensor, said second pressure sensor, and said third pressure sensor, controlling and changing over time a first water injection pressure at which water is injected into said second permeable layer through said at least one set of second perforations. 8. A method according to claim 7, wherein: said controlling and changing over time is controlled and changed according to ⅆpwiⅆt=κwpwms-pwmυwsgn(pwms-pwm)[1-H(pwi-pwiM)H(pwms-pwm)] where pwi is said first water injection pressure, pwm is a water interval measured pressure obtained from said second pressure sensor and said third pressure sensor, pwms is a set point for the water interval measured pressure, κw is a control parameter, υw is a sensitivity exponent, sgn indicates the sign function, H is a function such that H(x)=1 when x≧0 and zero otherwise, and pwiM, is a maximum injection pressure. 9. A method according to claim 8, wherein: said feedback control algorithm controls and changes over time a carbon dioxide injection pressure at which the carbon dioxide is injected into said first permeable layer through said first set of perforations. 10. A method according to claim 8, wherein: said feedback control algorithm controls and changes over time said carbon dioxide injection pressure according to ⅆpgiⅆt=κg0pgiM-pgiυg0sgn(pgiM-pgi)H(pwiMɛ-pwi)- [κg1pwm-pwmsυg1H(pwms-pwm)]×[1-H(pwiMɛ-pwi)] where pgi is said carbon dioxide injection pressure, pgiM is a maximum carbon dioxide injection pressure, pgiMε is a carbon dioxide injection pressure slightly below said maximum carbon dioxide injection pressure, κg0 and κg1 are nonnegative control coefficients, and υg0 and υg1 are sensitivity exponents. 11. A method according to claim 7, wherein: said at least two completions comprises at least three completions, and said at least one set of second perforations in the casing along said at least one length comprises at least a first set and a second set of second perforations, and said feedback control algorithm controls and changes over time said first water injection pressure at which water is injected through said first set of second perforations and a second water injection pressure at which water is injected into said second permeable layer through said second set of second perforations. 12. A method according to claim 11, wherein: said feedback control algorithm controls and changes over time said first water injection pressure at which water is injected through said first set of second perforations and a second water injection pressure at which water is injected into said second permeable layer through said second set of second perforations according to ⅆpwi1ⅆt=[κ11pwm1s-pwm1υw11sgn(pwm1s-pwm1)+κ12pwm2s-pwm2υw12sgn(pwm2s-pwm2)] [1-H(pwi1-pwi1M)H(A1)]whereA1=[κ11pwm1s-pwm1υw11sgn(pwm1s-pwm1)+κ12pwm2s-pwm2υw12sgn(pwm2s-pwm2)]andⅆpwi2ⅆt=[κ21pwm1s-pwm1υw21sgn(pwm1s-pwm1)+κ22pwm2s-pwm2υw22sgn(pwm2s-pwm2)] [1-H(pwi2-pwi2M)H(A2)]withA2=[κ21pwm1s-pwm1υw21sgn(pwm1s-pwm1)+κ22pwm2s-pwm2υw22sgn(pwm2s-pwm2)], where pwi1 is said first water injection pressure, pwi2 is said second water injection pressure, pwm1 is a measured water pressure obtained from said second pressure sensor, pwm2 is a measured water pressure obtained from and said third pressure sensor, pwm1s is a set point for the first water pressure, pwm2s is a set point for the second water pressure, pwi1M is a maximum first water injection pressure, pwi2M is a maximum second water injection pressure, κ11, κ12, κ21, and κ22 are a first set of nonnegative control coefficients, υw11, υw12, υw21, and υw22 are a first set of sensitivity exponents, sgn indicates the sign function, and H is a function such that H(x)=1 when x≧0 and zero otherwise. 13. A method according to claim 11, wherein: said feedback control algorithm controls and changes over time a carbon dioxide injection pressure at which the carbon dioxide is injected into said first permeable layer through said first set of perforations. 14. A method according to claim 12, wherein: said feedback control algorithm controls and changes over time a carbon dioxide injection pressure at which the carbon dioxide is injected into said first permeable layer through said first set of perforations according to ⅆpgiⅆt=κg0pgiM-pgiυg0sgn(pgiM-pgi)H(pwi2Mɛ-pwi2)H(pwi1Mɛ-pwi1)-[κg1pwm1-pwm1sυg1H(pwm1s-pwm1)+κg2pwm2s-pwm2υg2H(pwm2s-pwm2)]× [1-H(pwi2Mɛ-pwi2)H(pwi1Mɛ-pwi1)] where pgi is said carbon dioxide injection pressure, pgiM is a maximum gas injection pressure, pwi1Mε is a first water injection pressure slightly below said maximum first water injection pressure, pwi2Mε is a second water injection pressure slightly below said maximum second water injection pressure, υg0, υg1, and υg2 are a second set of nonnegative control coefficients, and υg0, υg1 and υg2 are a second set of sensitivity exponents. 15. A method according to claim 14, wherein: said first set of sensitivity components and said second set of sensitivity components are set to one. 16. A method according to claim 12, wherein: said first water injection pressure at which water is injected through said first set of second perforations is driven by a target pressure of pwm1s=pgm0−ρgg(z0−zm0)+ρwg(z0−zm1)−(1−α1)pb where pwm1s is a target measurement pressure of said second pressure sensor, pb is the entry capillary pressure, α1 is a first safety factor which is less than unity but greater than zero, g is the gravity constant, ρg and ρw are the densities of the injected carbon dioxide and the injected water respectively, z0, zm0 and zm1 are respectively an interface location between the first permeable layer and the first nearly impermeable layer, a pressure measurement location for said first permeable layer, and a first pressure measurement location for said second permeable layer, and pgm0 is the pressure measured by said first pressure sensor. 17. A method according to claim 16, wherein: said second water injection pressure at which water is injected into said second permeable layer through said second set of second perforations is driven by a target pressure of pwm2s=pgm0*−ρgg(z0−zm0)+ρwg(z0−zm2)−(1−α2)pb where pwm2s is a target measurement pressure of said third pressure sensor, α2 is a second safety factor which is less than unity but greater than zero, and pgm0* is an estimated pressure which would be measured by said first pressure sensor at a radius of investigation. 18. A method for sequestration of carbon dioxide in a formation having a first permeable layer directly overlain by a nearly impermeable layer, which in turn is overlain by a second permeable layer, the formation being traversed by a cased wellbore, comprising: a) completing the wellbore with at least three completions, with first perforations in the casing along said first permeable layer for the purpose of injecting carbon dioxide into the first permeable layer and with at least two sets of second perforations in the casing along said second permeable layer for the purpose of injecting water into the second permeable layer, and with a first pressure sensor along said formation which senses pressure in said first permeable layer, a second pressure sensor along said formation which senses pressure at a first location in said second permeable layer, and a third pressure sensor along said formation which senses pressure at a second location in said second permeable layer; andb) simultaneously injecting carbon dioxide into said first permeable layer through said first perforations and water into said second permeable layer separately through said at least two sets of second perforations, where the carbon dioxide and water is injected using a feedback control algorithm which utilizes readings of said first pressure sensor, said second pressure sensor, and said third pressure sensor, and controls and changes over time a carbon dioxide injection pressure, and both first and second water injection pressures at which water is injected into said second permeable layer. 19. A method according to claim 18, wherein: said first pressure sensor is located just below said nearly impermeable layer, said second pressure sensor is located just above said nearly impermeable layer, and said feedback control algorithm minimizes a pressure difference between water and carbon dioxide across said nearly impermeable layer corrected by a fraction of an entry capillary pressure into said nearly impermeable layer and for gravity. 20. A method according to claim 19, wherein: said third pressure sensor is located at a top of said second permeable layer. 21. A system for sequestration of carbon dioxide in a formation having a surface and thereunder a first permeable layer directly overlain by a nearly impermeable layer, which in turn is overlain by a second permeable layer, the formation being traversed by a cased wellbore, comprising: a) a first pump coupled to a source of carbon dioxide;b) second and third pumps coupled to at least one source of water;c) a triple completion of the cased wellbore, said triple completion coupled to said first pump, said second pump, and said third pump and providing independent communication between the surface and the first permeable layer and between the surface and a first location in said second permeable layer and between the surface and a second location in said second permeable layer, wherein said first pump pumps the supercritical carbon dioxide down the third completion and into the first permeable layer at a first injection pressure, and simultaneously the second pump pumps water down the triple completion and into a first location in the second permeable layer at a second injection pressure, said second injection pressure at least equal to said first injection pressure plus a gravitational head correction minus an entry capillary pressure correction for the water, and simultaneously the third pump pumps water down the triple completion and into a second location in the second permeable layer at a third injection pressure. 22. A system according to claim 21, further comprising: a first pressure sensor located along said formation which senses pressure in said first permeable layer;a second pressure sensor located along said formation which senses pressure at a first location in said second permeable layer;a third pressure sensor located along said formation which senses pressure at a second location in said second permeable layer; anda feedback control system coupled to said first pressure sensor, said second pressure sensor, said third pressure sensor, and said first pump, said second pump, and said third pump, wherein said feedback control system utilizes readings of said first pressure sensor, said second pressure sensor, and said third pressure sensor, and controls and changes over time a carbon dioxide injection pressure applied by said first pump, and first and second water injection pressures at which water is injected into said second permeable layer by said second and third pumps.
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