Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Initial Prototype Presentation
Document related concepts
Transcript
Eelectric Energy Harvesting Through Piezoelectric Polymers Initial Prototype Presentation Don Jenket, II Kathy Li Peter Stone Presentation Overview Design Schematics Materials & Processing Justification Circuitry Tail Wire/Electrodes Initial Prototype Unveiling Improvements for Final Design Revised Timeline April 13, 2004 Eelectric Initial Prototype Design Schematic Fan Rectifier Electronics Housing April 13, 2004 Eelectric Initial Prototype Circuitry Schematic Diodes LED AC Capacitors April 13, 2004 Eelectric Initial Prototype Materials & Processing Justifications Circuitry – Germanium diodes Require less voltage to bias (0.2V) Fewest diodes used as possible Fewer voltage drops Less power consumed by the circuit Storage Device Capacitors used to store energy April 13, 2004 Eelectric Initial Prototype “Eel Tail” Schematic 12 cm Tail End Head End Top View 2 cm Cu Wire Titanium Electrode Cu Wire Silver paste Titanium Electrodes 12 cm 2 cm Side View April 13, 2004 0.04 mm Front View Eelectric Initial Prototype Materials & Processing Justifications Tail, Material – PVDF April 13, 2004 Eelectric Initial Prototype Materials & Processing Justifications Tail, Aspect Ratio – 2 cm x 12 cm April 13, 2004 Eelectric Initial Prototype Materials & Processing Justifications Electrodes – Titanium & Silver Paste Gold desired in place of Titanium Easier processing Better properties in air Wires – 5 mil insulated magnet wire Flexible Coiled, Wound, Twisted – noise reduction Can come in contact with other conductors (i.e. flagpole) April 13, 2004 Eelectric Initial Prototype Oscilloscope Data 2cm x 12cm Piezoelectric PVDF in Wind April 13, 2004 Eelectric Initial Prototype Circuitry Schematic Diodes LED AC Capacitors April 13, 2004 Eelectric Initial Prototype Current Progress Working piezoelectric AC Source AC Voltage ~700 mV peak-to-peak Working rectifying circuit Takes >2000 mV AC peak-to-peak to light an LED What needs to be done? Increase Voltage Output from PVDF Tail Connecting multiple tails in series Integrate the two working components April 13, 2004 Eelectric Initial Prototype Improvements on Final Design Layering Two layers Increases possible output Decreases flexibility Difficult to adhere together Adhesive reinforcement Silver Paste alone cannot hold layers together or wires down Kapton and Mylar Tape 2-5 mil thickness should not drastically alter flexibility April 13, 2004 Eelectric Initial Prototype Improvements on Final Design Electrode & Wiring Modifications 12 cm Silver Electrode Cu Wire PVDF 2 cm Gold Electrode Allows for bending freedom Strain relief of wire Run wire straight to flagpole April 13, 2004 Eelectric Initial Prototype Revised Timeline 2/10 2/17 2/24 3/2 3/9 3/16 3/23 4/6 4/13 4/20 4/27 5/4 Electroded piezoelectronic sample Obtain PVDF Investigate electrode technology Attach electrodes to PVDF Preliminary measurements Build Prototype Electronic Circuitry Test Prototype Air testing Output measurement Optimizing Prototype Incorporating future revisions Build prototype II Test protoype II Prepare Demo Final Presentation April 13, 2004 Eelectric Initial Prototype 5/11
