IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0728263
(2000-11-28)
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발명자
/ 주소 |
- Bergh, H. Sam
- Guan, Shenheng
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출원인 / 주소 |
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인용정보 |
피인용 횟수 :
18 인용 특허 :
86 |
초록
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A chemical processing microsystem useful for identifying and optimizing materials (e.g., catalysts) that enhance chemical processes or for characterizing and/or optimizing chemical processes is disclosed. The chemical processing microsystem comprises a plurality of microreactors 600 and, in a prefer
A chemical processing microsystem useful for identifying and optimizing materials (e.g., catalysts) that enhance chemical processes or for characterizing and/or optimizing chemical processes is disclosed. The chemical processing microsystem comprises a plurality of microreactors 600 and, in a preferred embodiment, a plurality of microseparators 900 integral with the chemical processing microsystem 10. The microreactors 600 are preferably diffusion-mixed microreactors formed in a plurality of laminae that include a modular, interchangeable candidate-material array 100. The material array 100 comprises a plurality of different candidate materials (e.g., catalysts), preferably arranged at separate, individually addressable portions of a substrate (e.g., wafer). The microseparators 900 are similarly formed in a plurality of laminae that include a modular, interchangeable adsorbent array 700. The adsorbent array 700 comprises one or more adsorbents, preferably arranged at separate, individually addressable portions of a substrate to spatially correspond to the plurality of different candidate materials. Modular microfluidic distribution systems are also disclosed. The chemical processing microsystem can be integrated into a material evaluation system that enables a comprehensive combinatorial material science research program.
대표청구항
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1. A microsystem comprisinga microfluidic manifold for distributing fluids in microfluidic systems, the manifold comprising a common port adaptable for fluid communication with one or more fluid sources or sinks, 2n terminal ports adaptable for fluid delivery to or fluid recovery from 2n microcompon
1. A microsystem comprisinga microfluidic manifold for distributing fluids in microfluidic systems, the manifold comprising a common port adaptable for fluid communication with one or more fluid sources or sinks, 2n terminal ports adaptable for fluid delivery to or fluid recovery from 2n microcomponents, n being an integer not less than 2, and a microfluidic distribution channel providing fluid communication between the common port and each of the 2n terminal ports, the distribution channel having a hydraulic radius of not more than about 2.5 mm and comprising 2n?1 channel sections connected with each other through 2n?1 binary junctions, each of the 2n?1 channel sections having at least three access ports serving as the common port, as a connection port for a binary junction, or as a terminal port, the distribution channel having a flow conductance that is substantially the same for each of the flow paths between the common port and each of the terminal ports, the manifold being further characterized by one or more of the features selected from the group consisting of (i) the 2n?1 channel sections are linear channel sections, (ii) n is an integer of not less than 6, and (iii) the 2n microcomponents are arranged in a substantially planar array with a planar density of not less than about 1 microcomponent/cm2, and 2n microcomponents adapted for receiving fluids from or discharging fluids to the respective 2n terminal ports. 2. The manifold of claim 1 wherein (a) one of the channel sections has access ports serving as the common port and as connection ports for two binary junctions, (b) [2n?1?2)] of the channel sections have access ports serving as connection ports for three binary junctions, and (c) [2n?1] of the channel sections have access ports serving as a connection port for one binary junction and as two terminal ports.3. The manifold of claim 1 wherein the microcomponents are microreactors comprising a surface defining a reaction cavity having a volume of not more than about 3 ml for carrying out a chemical reaction, and at least one microreactor inlet port and at least one microreactor outlet port in fluid communication with the reaction cavity for fluid flow through the reaction cavity.4. The manifold of claim 1 wherein each of the microcomponents have an inlet port and an outlet port for fluid flow through the microcomponent, and the distribution channel has a pressure drop for each of the flow paths between the common port and each of the terminal ports that is greater than the pressure drop in the microcomponent.5. The manifold of claim 1 wherein the length of a total flowpath between the common port and each terminal port is the same.6. The manifold of claim 1 wherein the change in pressure between the common port and each terminal port is the same.7. The manifold of claim 1 wherein the change in pressure between the common port and each terminal port is substantially linear.8. The manifold of claim 1 wherein n is not less than 8.9. The manifold of claim 1 wherein n is not less than 10.10. The manifold of claim 1 wherein each of the channel sections of the distribution channel are substantially coplanar.11. The manifold of claim 1 wherein the microfluidic distribution channel provides simultaneously fluid communication between the common port and each of the 2n terminal ports.12. A microsystem comprisinga microfluidic manifold for distributing fluids in microfluidic systems, the manifold comprising, in a substantially coplanar structure, a common port adaptable for fluid communication with one or more fluid sources or sinks, 2n terminal ports adaptable for fluid delivery to or fluid recovery from 2n microcomponents, n being an integer not less than 2, and a microfluidic distribution channel providing simultaneous fluid communication between the common port and each of the 2n terminal ports, the distribution channel having a hydraulic radius of not more than about 2.5 mm and comprising channel sections connected with each other through 2n?1 binary junctions, each of the 2n?1 channel sections having at least three access ports serving as the common port, as a connection port for a binary junction, or as a terminal port, the manifold being further characterized by one or more of the features selected from the group consisting of (i) the 2n?1 channel sections are linear channel sections, (ii) n is an integer of not less than 6, and (iii) the 2n microcomponents are arranged in a substantially planar array with a planar density of not less than about 1 microcomponent/cm2, and 2n microcomponents adapted for receiving fluids from or discharging fluids to the respective 2n terminal ports. 13. A microsystem comprisinga microfluidic manifold for distributing fluids in microfluidic systems, the manifold comprising, a common port adaptable for fluid communication with one or more fluid sources or sinks, 2n terminal ports adaptable for fluid delivery to or fluid recovery from 2n microcomponents, n being an integer not less than 2, and a passive microfluidic fluid distribution channel providing simultaneous fluid communication between the common port and each of the 2n terminal ports, the distribution channel having a hydraulic radius of not more than about 2.5 mm and comprising 2n?1 channel sections connected with each other through 2n?1 binary junctions, each of the 2n?1 channel sections having at least three access ports serving as the common port, as a connection port for a binary junction, or as a terminal port, the manifold being further characterized by one or more of the features selected from the group consisting of (i) the 2n?1 channel sections are linear channel sections, (ii) n is an integer of not less than 6, and (iii) the 2n microcomponents are arranged in a substantially planar array with a planar density of not less than about 1 microcomponent/cm2, and 2n microcomponents adapted for receiving fluids from or discharging fluids to the respective 2n terminal ports. 14. A microsystem comprisinga microfluidic manifold for distributing fluids in microfluidic systems, the manifold comprising, in a substantially coplanar structure, a common port adaptable for fluid communication with one or more fluid sources or sinks, 2n terminal ports adaptable for fluid delivery to or fluid recovery from 2n microcomponents, n being an integer not less than 2, each of the microcomponents have an inlet port and an outlet port for fluid flow through the microcomponent, and a passive microfluidic distribution channel providing simultaneous fluid communication between the common port and each of the 2n terminal ports, the distribution channel having a hydraulic radius of not more than about 2.5 mm and comprising 2n?1 channel sections connected with each other through 2n?1 binary junctions, each of the 2n?1 channel sections having at least three access ports serving as the common port, as a connection port for a binary junction, or as a terminal port, the distribution channel having, a flow conductance that is substantially the same for each of the flow paths between the common port and each of the terminal ports, the distribution channel having a pressure drop for each of the flow paths between the common port and each of the terminal ports that is greater than the pressure drop in the microreactor, the manifold being further characterized by one or more of the features selected from the group consisting of (i) the 2n?1 channel sections are linear channel sections, (ii) n is an integer of not less than 6, and (iii) the 2n microcomponents are arranged in a substantially planar array with a planar density of not less than about 1 microcomponent/cm2, and 2n microcomponents adapted for receiving fluids from or discharging fluids to the respective 2n terminal ports. 15. A microsystem comprisinga microfluidic distribution system for distributing fluids in a microfluidic system, comprising a microfluidic fluid-supply manifold for simultaneously supplying a fluid from a fluid source to each of 2n microcomponents, n being an integer not less than 2, the microfluidic fluid-supply manifold comprising a common supply port adaptable for fluid communication with the fluid source, 2n terminal supply ports adaptable for fluid delivery to the 2n microcomponents, and a supply distribution channel providing fluid communication between the common supply port and each of the 2n terminal supply ports, the supply distribution channel having a hydraulic radius of not more than about 2.5 mm and comprising 2n?1 supply channel sections connected with each other through 2n?1 supply binary junctions, each of the 2n?1 supply channel sections having at least three supply access ports serving as the common supply port, as a connection port for a supply binary junction, or as a terminal supply port, and 2n microcomponents adapted for receiving fluids from the respective 2n terminal supply ports and discharging fluid to respective 2n terminal effluent ports of a microfluidic effluent-distribution manifold, a microfluidic effluent-distribution manifold for simultaneously discharging an effluent fluid from each of 2n microcomponents to a single common effluent sink, the microfluidic effluent-distribution manifold comprising 2n terminal effluent ports adaptable for fluid recovery from 2n microcomponents, a common effluent port adaptable for fluid communication with the effluent sink, and an effluent distribution channel providing fluid communication between each of the 2n terminal ports and the common effluent port, the effluent distribution channel having a hydraulic radius of not more than about 2.5 mm and comprising 2n?1 effluent channel sections connected with each other through 2n?1 effluent binary junctions, each of the 2n?1 effluent channel sections having at least three effluent access ports serving as the common effluent port, as a connection port for an effluent binary junction, or as a terminal effluent port, each of the microfluidic fluid-supply manifold and the microfluidic effluent-distribution manifold being further characterized by one or more of the features selected from the group consisting of (i) the 2n?1 channel sections are linear channel sections, (ii) n is an integer of not less than 6, and (iii) the 2n microcomponents are arranged in a substantially planar array with a planar density of not less than about 1 microcomponent/cm2.
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