The present disclosure describes a spiral cross-flow filter. The spiral cross-flow filter includes a filter element having a continuous web of leaves formed by pleating a laminate filter element. The filter element may include a composite filter material including a first layer of a membrane materia
The present disclosure describes a spiral cross-flow filter. The spiral cross-flow filter includes a filter element having a continuous web of leaves formed by pleating a laminate filter element. The filter element may include a composite filter material including a first layer of a membrane material adjacent an outer shell, and a second layer of a permeate spacer material adjacent a permeate tube. The plurality of leaves wrap around the permeate tube in a uniform “spiral” configuration and may be separated by feed spacers.
대표청구항▼
1. A spiral cross-flow filter, comprising: an outer shell;a permeate tube coaxially aligned within the outer shell and radially offset therefrom; anda pleated filter element comprising pleats located within an annulus between the outer shell and the permeate tube, the filter element comprising a com
1. A spiral cross-flow filter, comprising: an outer shell;a permeate tube coaxially aligned within the outer shell and radially offset therefrom; anda pleated filter element comprising pleats located within an annulus between the outer shell and the permeate tube, the filter element comprising a composite filter material comprising: a first layer of a membrane material adjacent the outer shell, anda second layer of a permeate spacer material adjacent the permeate tube,the pleats of the filter element defining a plurality of circumferentially spaced leaves, wherein the plurality of leaves wrap around the permeate tube in a uniform direction, wherein each leaf comprises an attachment to the permeate tube at a proximal edge of the leaf, and wherein each attachment comprises a direct bond between the permeate tube and the membrane material;wherein a middle portion of the permeate tube is blocked and configured to direct fluid out of the permeate tube, into the plurality of leaves, and back into the permeate tube downstream from the blocked middle portion of the permeate tube. 2. The filter of claim 1, wherein the permeate tube comprises at least one manifold formed by a perforated section of a cylindrical wall of the permeate tube, which is radially offset inwardly away from an outer cylindrical surface of the middle portion of the permeate tube, and which is radially offset inwardly away from an outer cylindrical surface of an inlet portion or an outlet portion of the permeate tube. 3. The filter of claim 2, wherein one or more leaves of the plurality of leaves of the filter element are attached to the permeate tube through attachments between edges of the leaves and an outer cylindrical surface of the permeate tube adjacent to the manifold. 4. The filter of claim 3, wherein the attachments do not comprise an adhesive. 5. The filter of claim 3, wherein the attachments comprise a bond between the edges of the leaves and an outer cylindrical surface of the permeate tube adjacent to the manifold, the bond formed by ultrasonic welding, thermal bonding, IR bonding, radio frequency bonding, microwave bonding, laser welding, or hot air welding. 6. The filter of claim 1, wherein the permeate tube comprises: a first manifold positioned adjacent to an inlet end of the permeate tube; anda second manifold positioned adjacent to an outlet end of the permeate tube;wherein the first manifold is formed by a perforated section of a cylindrical wall of a hollow inlet portion of the permeate tube, wherein the perforated section is radially offset inwardly away from an outer cylindrical surface of the middle portion of the permeate tube, and is radially offset inwardly away from an outer cylindrical surface of the hollow inlet portion of the permeate tube; andwherein the second manifold is formed by a perforated section of a cylindrical wall of a hollow outlet portion of the permeate tube, wherein the perforated section is radially offset inwardly away from an outer cylindrical surface of the middle portion of the permeate tube, and is radially offset inwardly away from an outer cylindrical surface of the hollow outlet portion of the permeate tube. 7. The filter of claim 6, wherein one or more leaves of the plurality of leaves of the filter element are attached to the permeate tube through attachments between edges of the leaves and an outer cylindrical surface of an inlet portion of the permeate tube adjacent to the first manifold, and wherein one or more leaves of the plurality of leaves of the filter element are attached to the permeate tube through attachments between edges of the leaves and an outer cylindrical surface of an outlet portion of the permeate tube adjacent to the second manifold. 8. The filter of claim 7, wherein the attachments do not comprise an adhesive. 9. The filter of claim 7, wherein the attachments comprise a bond formed by ultrasonic welding, thermal bonding, IR bonding, radio frequency bonding, microwave bonding, laser welding, or hot air welding. 10. The filter of claim 1, wherein one or more leaves of the plurality of leaves of the filter element are attached to the permeate tube through attachments between edges of the leaves and an outer cylindrical surface of the permeate tube. 11. The filter of claim 10, wherein the attachments do not comprise an adhesive. 12. The filter of claim 10, wherein the attachments comprise a bond formed by ultrasonic welding, thermal bonding, IR bonding, radio frequency bonding, microwave bonding, laser welding, or hot air welding. 13. The filter of claim 1, further comprising feed spacers positioned in between each of the plurality of leaves. 14. The filter of claim 1, further comprising an inlet end cap attached to an inlet end of the permeate tube, and an outlet end cap attached to an outlet end of the permeate tube. 15. The filter of claim 14, wherein the inlet end cap and the outlet end cap are attached to the outer cylindrical shell and the permeate tube with bonds that do not comprise an adhesive. 16. The filter of claim 1, wherein each leaf of the plurality of leaves comprises a bond along at least a portion of an inlet edge and along at least a portion of an outlet edge of the filter element, the bond sealing together adjacent pleats of the filter element to provide each leaf with a fluid impervious seal at the inlet edge and the outlet edge of the filter element. 17. The filter of claim 16, wherein the bonds do not comprise an adhesive. 18. The filter of claim 16, wherein the bonds are formed by ultrasonic welding, thermal bonding, IR bonding, radio frequency bonding, microwave bonding, laser welding, or hot air welding. 19. The filter of claim 1, wherein the plurality of leaves comprises a ratio of leaf height to spiral diameter of less than or equal to 3. 20. A spiral cross-flow filter, comprising: an outer shell;a permeate tube coaxially aligned within the outer shell and radially offset therefrom, the permeate tube comprising: a blocked middle portion;a hollow inlet portion comprising a first manifold formed by a perforated section of a cylindrical wall of the inlet portion, wherein the perforated section is radially offset inwardly away from an outer cylindrical surface of the blocked middle portion of the permeate tube, and is radially offset inwardly away from an outer cylindrical surface of the hollow inlet portion of the permeate tube; anda hollow outlet portion comprising a second manifold formed by a perforated section of a cylindrical wall of the outlet portion, wherein the perforated section is radially offset inwardly away from an outer cylindrical surface of the blocked middle portion of the permeate tube, and is radially offset inwardly away from an outer cylindrical surface of the hollow outlet portion of the permeate tube; anda pleated filter element comprising pleats located within an annulus between the outer shell and the permeate tube, the filter element comprising a composite filter material comprising: a first layer of a membrane material adjacent the outer shell; anda second layer of a permeate spacer material adjacent the permeate tube,the pleats of the filter element defining a plurality of circumferentially spaced leaves, wherein the plurality of leaves wrap around the permeate tube in a uniform direction, wherein each leaf comprises an attachment to the permeate tube at a proximal edge of the leaf, and wherein each attachment comprises a direct bond between the permeate tube and the membrane material. 21. The filter of claim 20, wherein one or more leaves of the plurality of leaves of the filter element are attached to the permeate tube through attachments between edges of the leaves and an outer cylindrical surface of the inlet portion of the permeate tube adjacent to the first manifold, and wherein one or more leaves of the plurality of leaves of the filter element are attached to the permeate tube through attachments between edges of the leaves and an outer cylindrical surface of the outlet portion of the permeate tube adjacent to the second manifold. 22. The filter of claim 21, wherein the attachments do not comprise an adhesive. 23. The filter of claim 21, wherein the attachments comprise a bond formed by ultrasonic welding, thermal bonding, IR bonding, radio frequency bonding, microwave bonding, laser welding, or hot air welding. 24. The filter of claim 20, wherein each leaf of the plurality of leaves comprises a bond along at least a portion of an inlet edge and along at least a portion of an outlet edge of the filter element, the bond sealing together adjacent pleats of the filter element to provide each leaf with a fluid impervious seal at the inlet edge and the outlet edge of the filter element. 25. The filter of claim 24, wherein the bonds do not comprise an adhesive. 26. The filter of claim 24, wherein the bonds are formed by ultrasonic welding, thermal bonding, IR bonding, radio frequency bonding, microwave bonding, laser welding, or hot air welding. 27. The filter of claim 20, wherein the plurality of leaves comprises a ratio of leaf height to spiral diameter of less than or equal to 3.
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이 특허에 인용된 특허 (10)
Downing Anthony L. (Welwyn GB2) Squires Rodney C. (South Godstone GB2), Cross-flow filtration.
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