An exemplary method for making a micropump device is disclosed as providing inter alia a substrate (300), an inlet opening (310), and outlet opening (340), a pump chamber (370) and flapper valves (350, 360). The fluid inlet channel (310) is generally configured to flow a fluid through/around the inl
An exemplary method for making a micropump device is disclosed as providing inter alia a substrate (300), an inlet opening (310), and outlet opening (340), a pump chamber (370) and flapper valves (350, 360). The fluid inlet channel (310) is generally configured to flow a fluid through/around the inlet opening flapper valve (350). The outlet opening flapper valve (360) generally provides means for preventing or otherwise decreasing the incidence of outlet fluid re-entering either the pumping cavity (370) and/or the fluid inlet channel (310). Accordingly, the reduction of backflow generally tends to enhance overall pumping efficiency. Disclosed features and specifications may be variously controlled, adapted or otherwise optionally modified to improve micropump operation in any microfluidic application. Exemplary embodiments of the present invention representatively provide for substantially self-priming gas/liquid micropumps that may be readily integrated with existing portable ceramic technologies for the improvement of device package form factors, weights and other manufacturing and/or device performance metrics.
대표청구항▼
1. A method for making a micropump device, comprising: providing a substrate, said substrate comprising a first surface and fluidic channels; said fluidic channels comprising an inlet channel, an outlet channel and a pumping cavity; said inlet channel suitably adapted to receive fluid for tr
1. A method for making a micropump device, comprising: providing a substrate, said substrate comprising a first surface and fluidic channels; said fluidic channels comprising an inlet channel, an outlet channel and a pumping cavity; said inlet channel suitably adapted to receive fluid for transport through said micropump device; said outlet channel suitably adapted to purge fluid from said micropump device; providing a first valve for effectively permitting flow of fluid from said inlet channel to said pumping cavity, said first valve effectively restricting backflow of purged fluid from said pumping cavity to said inlet, and said first valve deposited through a first opening on said first surface of said substrate and in sealing engagement with said substrate; providing a second valve for effectively permitting flow of fluid from said pumping cavity to said outlet channel, said second valve effectively restricting backflow of purged fluid from said outlet channel to said pumping cavity, and said second valve deposited through a second opening on said first surface of said substrate and in sealing engagement with said substrate; effectively disposing a pump actuator over said first opening and covering said first valve; and providing a cover for substantially sealing said second opening and covering said second valve. 2. The method of claim 1, wherein said first valve and said second valve comprise at least one of a check valve, a passive check valve and a flapper valve.3. The method of claim 2, wherein said first valve and said second valve comprise at least one of silicone, silicone-based rubber, rubber, metal, metal alloy and polymer.4. The method of claim 1, wherein said pump actuator comprises a piezoelectric element.5. The method of claim 1, further comprising the step of providing means for retaining at least one of said first valve and said second valve within a microfluidic channel.6. The method of claim 5, wherein said retaining means comprises a substantially annular retaining ring.7. The method of claim 1, wherein at least one of said pump actuator and said cover are soldered to said first surface of said substrate.8. A microfluidic pumping device manufactured in accordance with the method of claim 1, wherein said pump actuator comprises a piezoelectric actuator.9. The microfluidic pumping device of claim 8, further comprising means for retaining at least one of said first valve and said second valve within a microfluidic channel.10. The microfluidic pumping device of claim 9, wherein said retaining means comprises a substantially annular retaining ring.11. The microfluidic pumping device of claim 8, wherein said piezoelectric actuator comprises at least one of a unimorphic piezoelectric element and a bimorphic piezoelectric element.12. A multilayer micropump device manufactured in accordance with the method of claim 1, wherein said substrate is a multilayer substrate comprising at least one of ceramic, metal, glass, polymer and wood.13. The multilayer micropump of claim 12, wherein said pump actuator comprises at least one of a unimorphic piezoelectric element and a bimorphic piezoelectric element.
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이 특허에 인용된 특허 (11)
Balma Antonio,ITX, Compressor having easily installed check valves.
Tani Michihiko,JPX ; Masaki Yasufumi,JPX, Method of measuring a pressure of a pressurized fluid fed through a diaphragm pump and accumulated in a vessel, and miniature pump system effecting the measurement.
Hk Bertil (Sportfiskaregatan 53 Vsters SEX S-723 48) Tenerz Lars (Ringgatan 20C Uppsala SEX S-752 27) Tirn Jonas (Geijersgatan 13C Uppsala SEX S-752 26), Micromechanical non-reverse valve.
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