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Multilayer Microfluidics

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Presentation on theme: "Multilayer Microfluidics"— Presentation transcript:

1 Multilayer Microfluidics
ENMA490 Fall 2003 Brought to you by: S. Beatty, C. Brooks, S. Dean, M. Hanna, D. Janiak, C. Kung, J. Ni, B. Sadowski, A. Samuel, K. Thaker Add picture (Anne)

2 Problem Definition Motivation Goal
BioMEMS research is growing rapidly, but restricted to single layer microfluidics Development of a multilayer microfluidic design would increase flexibility Goal Design, construct, and test a controllable microfluidic device with at least two fluid levels. Identify appropriate materials, processes, and device geometries. Add pictures. Show old and new. (Dan)

3 Problem Scope Requirements Constraints
To make a two-level microfluidic device To incorporate active control elements Constraints Assume external fluid control Neglect biochemical reactions in channels Keep design feasible for manufacturing

4 Initial Material Choices
Narrowing Materials Choices Desired Mechanical and electrical properties Process considerations Create materials table: rigid SU8, flexible PDMS, Pyrex and silicon as substrates. (Anne, Charles)

5 Project Development Map out development process (Chen, Dave)

6 Device Design: Stage 1 (Initial Microchannel Design Concept)
Device Logic (Anne, Susan, Kunal)

7 Device Design: Stage 1 (Initial Microchannel Design Concept)
(Anne, Susan, Kunal)

8 Device Design: Stage 2 (Modified Microchannel Design)
Device Logic (Anne, Susan, Kunal)

9 Device Design: Stage 2 (Modified Microchannel Design)
(Anne, Susan, Kunal)

10 Device Design: Stage 2 (Modified Microchannel Design)
Manufacturing and experimental results (Mark, Dan)

11 Device Design: Stage 3 (Pressure Actuated Valve Design)
Device Logic (Shawna, Charles, Bryan)

12 Device Design: Stage 3 (Pressure Actuated Valve Design)
(Shawna, Charles, Bryan)

13 Device Design: Stage 3 (Pressure Actuated Valve Design)
Simulation PDMS deflection (Shawna)

14 Device Design: Stage 3 (Pressure Actuated Valve Design)
Flow modeling (Bryan, Kunal)

15 Device Design: Stage 3 (Pressure Actuated Valve Design)
Manufacturing and experimental results (Dan, Mark)

16 Alternative Designs (Anne, Susan, Charles, Chen)

17 Future Work (Shawna)

18 Summary (Chen, Dave)

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