Flow device
First Claim
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1. A novel flow device comprising a conduit which comprises (1) a barrier member, and (2) a porous flow member (PFM) which (i) comprises a solid porous material, and (ii) is enclosed by the barrier member so that the PFM comprises a flowthrough section through which there can be electroosmotic and/or pressure-driven flow of a liquid;
- the device having at least one of the following characteristics (A) the barrier member comprises a plurality of laminar barrier layers which have been laminated together around the PFM;
(B) the PFM is a pre-shaped PFM, or, if the device comprises more than one said conduit, the PFM in at least one of said conduits, e.g. the PFM in each of said conduits, is a pre-shaped PFM;
(C) the PFM is laminar and lies in a first plane, and the device comprises a conduit which (i) is in fluidic communication with the PFM, and (ii) lies in the first plane or in a plane substantially parallel to the first plane;
(D) the PFM is laminar and lies in a first plane, and the device comprises an electrode which (i) when the device is filled with an ionic liquid, is in electrical communication with the PFM, and (ii) lies in the first plane or in a plane substantially parallel to the first plane;
(E) the device comprises at least four laminar layers, at least two of the laminar layers comprising a laminar PFM;
(F) the device comprises (1) a first said conduit comprising a first barrier member and a first PFM which comprises a first flowthrough section and a first transfer section, the first flowthrough section being enclosed by the first barrier member so that fluid can flow the first flowthrough section and into the first transfer section, (2) a second said conduit comprising a second barrier member and a second PFM which comprises a second flowthrough section and a second transfer section, the second flowthrough section being enclosed by the second barrier member so that fluid can flow through the first flowthrough section and into the second transfer section;
the first and second transfer sections (a) having overlapping surfaces which (i) contact each other directly, or (ii) are adjacent to each other and are separated from each other by a gap which optionally is filled by a porous material, and (b) being enclosed by a third barrier member so that liquids flowing into the first and second transfer sections are mixed together;
(G) the device comprises (1) a first said conduit in which the flowthrough section of the PFM is a first laminar PFM which lies in a first plane, (2) a second said conduit in which the flowthrough section of the PFM is a second laminar PFM which lies in a second plane parallel to first plane and which overlaps the flowthrough section of the first conduit;
(H1) the PFM comprises (a) a first layer which is composed of a first porous material, (b) a second layer which is in contact with the first layer along an interface and which is composed of second porous material, the first porous material having a first pore size and second porous material having a second pore size which is larger than the first pore size, or the pore geometry of the first porous material at the interface being such that particles above a certain pore size will not pass through the interface, and the device further comprises (3) a fluidic inlet which communicates with the second layer but not with the first layer, (4) a first fluidic exit which communicates with the first layer but not with the second layer, and (5) a second fluidic exit which communicates with second layer but not with the first layer;
(H2) the PFM is composed of a porous material having an asymmetric pore size distribution such that the pore size increases, regularly or irregularly, across the thickness of the PFM, whereby the PFM has a first surface composed of relatively small pores and a second surface composed of relatively large pores, and the device further comprises (3) a fluidic inlet which communicates with the PFM, (4) a first fluidic exit which communicates with the first surface but not with the second surface, and (5) a second fluidic exit which communicates with second surface but not with the first surface;
(I) the device comprises (1) a first said conduit in which the PFM comprises a first solid porous material having a first zeta potential, the first conduit having a first inner end and first outer end, (2) a second said conduit in which the PFM comprises a second solid porous material having a second zeta potential which is substantially different from the first zeta potential, the second conduit having a second inner end and a second outer end, (3) an inner fluidic junction which communicates with the first and second inner ends, (4) a first outer fluidic junction which communicates with the first outer end, and (5) a second outer fluidic junction which communicates with the second outer end;
(J) the device comprises (1) a first said conduit in which the flowthrough section of the PFM terminates at a first cross-sectional end surface;
(2) a second said conduit in which the flowthrough section of the PFM terminates at a second cross-sectional end surface which contacts the first surface at a butt junction; and
(3) an auxiliary porous member which contacts the sides of the first and second PFMs and bridges the butt junction;
(K) the PFM has a cross-section having a thickness of less than 4000 microns;
(L) the PFM has a cross-section having an equivalent diameter of less than 4000 microns; and
(M) the conduit is rigid.
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Abstract
Liquid flow devices, particularly microfluidic devices, containing solid porous materials. Flow in the devices can be pressure-driven flow and/or electroosmotic flow. The porous materials are preferably pre-shaped, for example divided from a sheet of porous material, so that they can be assembled with liquid-impermeable barrier materials around them. The devices can for example be prepared by lamination. A wide variety of devices, including mixing devices, is disclosed. A mixing device is illustrated in FIG. 23.
80 Citations
14 Claims
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1. A novel flow device comprising a conduit which comprises
(1) a barrier member, and (2) a porous flow member (PFM) which (i) comprises a solid porous material, and (ii) is enclosed by the barrier member so that the PFM comprises a flowthrough section through which there can be electroosmotic and/or pressure-driven flow of a liquid; -
the device having at least one of the following characteristics (A) the barrier member comprises a plurality of laminar barrier layers which have been laminated together around the PFM;
(B) the PFM is a pre-shaped PFM, or, if the device comprises more than one said conduit, the PFM in at least one of said conduits, e.g. the PFM in each of said conduits, is a pre-shaped PFM;
(C) the PFM is laminar and lies in a first plane, and the device comprises a conduit which (i) is in fluidic communication with the PFM, and (ii) lies in the first plane or in a plane substantially parallel to the first plane;
(D) the PFM is laminar and lies in a first plane, and the device comprises an electrode which (i) when the device is filled with an ionic liquid, is in electrical communication with the PFM, and (ii) lies in the first plane or in a plane substantially parallel to the first plane;
(E) the device comprises at least four laminar layers, at least two of the laminar layers comprising a laminar PFM;
(F) the device comprises (1) a first said conduit comprising a first barrier member and a first PFM which comprises a first flowthrough section and a first transfer section, the first flowthrough section being enclosed by the first barrier member so that fluid can flow the first flowthrough section and into the first transfer section, (2) a second said conduit comprising a second barrier member and a second PFM which comprises a second flowthrough section and a second transfer section, the second flowthrough section being enclosed by the second barrier member so that fluid can flow through the first flowthrough section and into the second transfer section;
the first and second transfer sections (a) having overlapping surfaces which (i) contact each other directly, or (ii) are adjacent to each other and are separated from each other by a gap which optionally is filled by a porous material, and (b) being enclosed by a third barrier member so that liquids flowing into the first and second transfer sections are mixed together;
(G) the device comprises (1) a first said conduit in which the flowthrough section of the PFM is a first laminar PFM which lies in a first plane, (2) a second said conduit in which the flowthrough section of the PFM is a second laminar PFM which lies in a second plane parallel to first plane and which overlaps the flowthrough section of the first conduit;
(H1) the PFM comprises (a) a first layer which is composed of a first porous material, (b) a second layer which is in contact with the first layer along an interface and which is composed of second porous material, the first porous material having a first pore size and second porous material having a second pore size which is larger than the first pore size, or the pore geometry of the first porous material at the interface being such that particles above a certain pore size will not pass through the interface, and the device further comprises (3) a fluidic inlet which communicates with the second layer but not with the first layer, (4) a first fluidic exit which communicates with the first layer but not with the second layer, and (5) a second fluidic exit which communicates with second layer but not with the first layer;
(H2) the PFM is composed of a porous material having an asymmetric pore size distribution such that the pore size increases, regularly or irregularly, across the thickness of the PFM, whereby the PFM has a first surface composed of relatively small pores and a second surface composed of relatively large pores, and the device further comprises (3) a fluidic inlet which communicates with the PFM, (4) a first fluidic exit which communicates with the first surface but not with the second surface, and (5) a second fluidic exit which communicates with second surface but not with the first surface;
(I) the device comprises (1) a first said conduit in which the PFM comprises a first solid porous material having a first zeta potential, the first conduit having a first inner end and first outer end, (2) a second said conduit in which the PFM comprises a second solid porous material having a second zeta potential which is substantially different from the first zeta potential, the second conduit having a second inner end and a second outer end, (3) an inner fluidic junction which communicates with the first and second inner ends, (4) a first outer fluidic junction which communicates with the first outer end, and (5) a second outer fluidic junction which communicates with the second outer end;
(J) the device comprises (1) a first said conduit in which the flowthrough section of the PFM terminates at a first cross-sectional end surface;
(2) a second said conduit in which the flowthrough section of the PFM terminates at a second cross-sectional end surface which contacts the first surface at a butt junction; and
(3) an auxiliary porous member which contacts the sides of the first and second PFMs and bridges the butt junction;
(K) the PFM has a cross-section having a thickness of less than 4000 microns;
(L) the PFM has a cross-section having an equivalent diameter of less than 4000 microns; and
(M) the conduit is rigid. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
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11. A method of preparing a conduit which comprises
(1) a barrier member, and (2) a porous flow member (PFM) which (i) comprises a solid porous material, and (ii) is enclosed by the barrier member so that the PFM comprises a flowthrough section through which there can be electroosmotic and/or pressure-driven flow of a liquid; the method comprising placing the flowthrough section of the PFM between a plurality of barrier layers, and laminating the barrier layers together to form the barrier member. - View Dependent Claims (12, 13)
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14. A method of preparing a conduit which comprises
(1) a barrier member, and (2) a porous flow member (PFM) which (i) comprises a solid porous material, and (ii) is enclosed by the barrier member so that the PFM comprises a flowthrough section through which there can be electroosmotic and/or pressure-driven flow of a liquid; the method comprising placing the flowthrough section of the PFM in a mold, placing a hardenable liquid composition in the mold around the PFM, and hardening the composition to encapsulate the flowthrough section.
Specification
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Current AssigneeTeleflex Life Sciences Pte., Ltd. (Teleflex Incorporated)
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Original AssigneeTeleflex Life Sciences Pte., Ltd. (Teleflex Incorporated)
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InventorsPaul, Philip H., Rehm, Jason E., Neyer, David W.
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Application NumberUS10/521,093Publication NumberTime in Patent OfficeDaysField of SearchUS Class Current204/450CPC Class CodesB01D 61/18 Apparatus thereforB01F 25/45 Mixers in which the materia...B01F 25/45221 the porous bodies being cyl...B01F 33/3031 using electro-hydrodynamic ...B01F 35/7172 using capillary forcesB01L 2300/0645 ElectrodesB01L 2300/0654 Lenses; Optical fibresB01L 2300/0681 FilterB01L 2300/0877 Flow chambersB01L 2300/0887 Laminated structureB01L 2400/0418 electro-osmotic flow [EOF]B01L 3/5023 with a sample being transpo...B01L 3/502707 characterised by the manufa...B01L 3/502753 characterised by bulk separ...F04B 19/006 Micropumps F04B43/043 and F...F04B 43/043 MicropumpsF04B 43/06 Pumps having fluid driveF16K 99/0001 Microvalves microdevices B8...F16K 99/0025 Valves using microporous me...F16K 99/0049 using an electroactive poly...View All
