IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0745992
(2003-12-24)
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발명자
/ 주소 |
- Miller,Stephen J.
- Kuperman,Alexander
- Vu,De Q.
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출원인 / 주소 |
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인용정보 |
피인용 횟수 :
23 인용 특허 :
27 |
초록
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A mixed matrix membrane is provided which comprises a continuous phase organic polymer and small pore molecular sieves dispersed therein. The molecular sieves have a largest minor crystallographic free diameter of 3.6 Angstroms or less. When these molecular sieves are properly interspersed with a co
A mixed matrix membrane is provided which comprises a continuous phase organic polymer and small pore molecular sieves dispersed therein. The molecular sieves have a largest minor crystallographic free diameter of 3.6 Angstroms or less. When these molecular sieves are properly interspersed with a continuous phase polymer, the membrane will exhibit a mixed matrix membrane effect, i.e., a selectivity increase of at least 10% relative to a neat membrane containing no molecular sieves. Finally, methods for making and using such mixed matrix membranes to separate gases from a mixture containing two or more gases are also disclosed.
대표청구항
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What is claimed is: 1. A mixed matrix membrane comprising: a continuous phase organic polymer and small pore molecular sieves dispersed therein, the molecular sieves having a largest minor crystallographic tree diameter of 3.6 Angstroms or less, wherein: the molecular sieves have an IZA structure t
What is claimed is: 1. A mixed matrix membrane comprising: a continuous phase organic polymer and small pore molecular sieves dispersed therein, the molecular sieves having a largest minor crystallographic tree diameter of 3.6 Angstroms or less, wherein: the molecular sieves have an IZA structure type of at least one of ERI, DDR, RHO, PAU, LEV, MER, AFX, AFT, and GIS; wherein the membrane exhibits a mixed matrix effect. 2. The mixed matrix membrane of claim 1 wherein: the molecular sieves have pores with a largest minor crystallographic free diameter in the range of 3.0-3.6 A. 3. The mixed matrix membrane of claim 1 wherein: the molecular sieves have pores with a largest minor crystallographic free diameter in the range of 3.0-3.4 A. 4. The mixed matrix membrane of claim 1 wherein: the molecular sieves have pores with a largest minor crystallographic free diameter in the range of 3.0-3.2 A. 5. The mixed matrix membrane of claim 1 wherein: the molecular sieves have an IZA structure type of at least one of MER, AFX, AFT, and GIS. 6. The mixed matrix membrane of claim 1 wherein: the molecular sieves have an IZA structure type of at least one of AFT and GIS. 7. The mixed matrix membrane ot claim 1 wherein: the molecular sieves have an IZA structure type of GIS. 8. The mixed matrix membrane of claim 1 wherein: the molecular sieves include at least one of AIPO-17, SAPO-17, CVX-7, ZSM-58, LZ-214, ECR-18, SAPO-35, Zeolite W, SAPO-56, AIPO-52, and SAPO-43. 9. The mixed matrix membrane of claim 1 wherein: the molecular sieves include at least one of Zeolite W, SAPO 56, AIPO-52, and SAPO-43. 10. The mixed matrix membrane of claim 1 wherein: the molecular sieves includes CVX-7; wherein a surface complexing agent is used to reduce the number average crystallite size of the CVX-7 molecular sieves. 11. The mixed matrix membrane of claim 1 wherein: the molecular sieves have an average particle size of less than 3 microns. 12. The mixed matrix membrane of claim 1 wherein: the molecular sieves have an average particle size between 0.2 to 3.0 microns. 13. The mixed matrix membrane of claim 1 wherein: the molecular sieves have an average particle size between 0.2 to 1.5 microns. 14. The mixed matrix membrane of claim 1 wherein: the molecular sieves have an average particle size between 0.2 to 0.7 microns. 15. The mixed matrix membrane of claim 1 wherein: the molecular sieves are generally elongate in morphology and have an aspect ratio of less than 10. 16. The mixed matrix membrane of claim 1 wherein: the molecular sieves are generally elongate in morphology and have an aspect ratio of less than 5. 17. The mixed matrix membrane of claim 1 wherein: the molecular sieves are generally elongate in morphology and have an aspect ratio between 1 and 3. 18. A method of making a mixed matrix membrane comprising: providing a continuous phase organic polymer; providing small pore molecular sieves having a largest minor crystallographic free diameter in the range of 3.0-3.6 Angstroms and an IZA structure type of at least one of ERI, DDR, RHO PAU, LEV, MER, AFX, AFT, and GIS; dispersing the molecular sieves into a solution containing the continuous phase organic polymer; and allowing the continuous phase organic polymer to solidify about the molecular sieves to produce a mixed matrix membrane; whereby the mixed matrix membrane exhibits a mixed matrix effect. 19. A process for separating gas components having different molecular sizes from a feed stream including the gas components, the process including: (a) providing a mixed matrix membrane having a continuous phase organic polymer and small pore molecular sieves dispersed therein, the molecular sieves having a minor crystallographic free diameter in the range of 3.0 to 3.6 Angrstroms and an IZA structure type of at least one of ERI, DDR, RHO, PAU, LEV, MER, AFX, AFT, and GIS, and the membrane including feed and permeate sides; and (b) directing a feedetream including first and second gas components to the feed side of the membrane and withdrawing a retentate stream depleted in the first gas component from the feed side and withdrawing a permeate stream enriched in the first gas component from the permeate side of the membrane. 20. A mixed matrix membrane comprising: a continuous phase organic polymer and small pore molecular sieves dispersed therein, the molecular sieves having a largest minor crystallographic free diameter of 3.6 Angstroms or less, and being generally elongate in morphology having an aspect ratio of less than 10; wherein the membrane exhibits a mixed matrix effect. 21. The mixed matrix membrane of claim 20, wherein the molecular sieves have pores with a largest minor crystallographic free diameter in the range of 3.0-3.6 A. 22. The mixed matrix membrane of claim 20, wherein the molecular sieves have pores with a largest minor crystallographic free diameter in the range of 3.0-3.4 A. 23. The mixed matrix membrane of claim 20, wherein the molecular sieves have pores with a largest minor crystallographic free diameter in the range of 3.0-3.2 A. 24. The mixed matrix membrane of claim 20, wherein the molecular sieves have an IZA structure type of at least one of ERI, DDR, RHO, PAU, LEV, MER, AFX, AFT, and GIS. 25. The mixed matrix membrane of claim 20, wherein the molecular sieves have an IZA structure type of at least one of MER, AFX, AFT, and GIS. 26. The mixed matrix membrane of claim 20, wherein the molecular sieves have an IZA structure type of at least one of AFT and GIS. 27. The mixed matrix membrane of claim 20, wherein the molecular sieves have an IZA structure type of GIS. 28. The mixed matrix membrane of claim 20, wherein the molecular sieves include at least one of AIPO-17, SAPO17, CVX-7, ZSM-58, LZ-214, ECR-18, SAPO-35, Zeolite W, SAPO-56, AIPO-52, and SAPO43. 29. The mixed matrix membrane of claim 20, wherein the molecular sieves include at least one of Zeolite W, SAPO-56, AIPO-52, and SAPO43. 30. The mixed matrix membrane of claim 20, wherein the molecular sieves includes CVX-7; wherein a surface complexing agent is used to reduce the number average crystallite size of the CVX-7 molecular sieves. 31. The mixed matrix membrane of claim 20, wherein the molecular sieves have an average particle size of less than 3 microns. 32. The mixed matrix membrane of claim 20, wherein the molecular sieves have an average particle size between 0.2 to 3.0 microns. 33. The mixed matrix membrane of claim 20, wherein the molecular sieves have an average particle size between 0.2 to 1.5 microns. 34. The mixed matrix membrane of claim 20, wherein the molecular sieves have an average particle size between 0.2 to 0.7 microns. 35. The mixed matrix membrane of claim 20, wherein the molecular sieves are generally elongate in morphology and have an aspect ratio of less than 10. 36. The mixed matrix membrane of claim 20, wherein the molecular sieves are generally elongate in morphology and have an aspect ratio between 1 and 3. 37. A method of making a mixed matrix membrane comprising: providing a continuous phase organic polymer; providing small pore molecular sieves having a largest minor crystallographic free diameter in the range of 3.0-3.6 Angstroms and being generally elongate in morphology having an aspect ratio of less than 10; dispersing the molecular sieves into a solution containing the continuous phase organic polymer; and allowing the continuous phase organic polymer to solidify about the molecular sieves to produce a mixed matrix membrane; whereby the mixed matrix membrane exhibits a mixed matrix effect. 38. A process for separating gas components having different molecular sizes from a feed stream including the gas components, the process including: (a) providing a mixed matrix membrane having a continuous phase organic polymer and small pore molecular sieves dispersed therein, the molecular sieves having a minor crystallographic free diameter in the range of 3.0 to 3.6 Angstroms and being generally elongate in morphology having an aspect ratio of less than 10, and the membrane including feed and permeate sides; and (b) directing a feedstream including first and second gas components to the feed side of the membrane and withdrawing a retentate stream depleted in the first gas component from the feed side and withdrawing a permeate stream enriched in the first gas component from the permeate side of the membrane.
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