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Transcript
MOBILE POWER STATION IRP Presentation December 10th 2010 Team: Brad Jensen William Klema Nathan Schares Advisor: Dr. Ayman Fayed Client: PowerFilm, Inc. PLANNING PROBLEM STATEMENT & SOLUTION Photovoltaic (PV) solar arrays can be used to power mobile devices; however, solar array output power is non-constant and most mobile device chargers require a constant voltage and current source. Team dec1013 purposed building a MPS that would supply a constant voltage and current to mobile devices, while tracking the maximum power point of a PV solar array. PLANNING CONCEPT SKETCH • Major Concepts • MPPT • DC-DC Charging • Li-Ion Battery Charging • Variable Source Solar Panel Source 120V AC Source (with AC/DC Adapter) MPPT Charging circuitry Batteries, 100W Power Distribution 12V DC PLANNING MARKET & USERS • MPS idea developed from market research by PowerFilm, Inc. • MPS focused mainly on military market • Designed to carry in backpack • Simple user interface • Connect source • Foldable solar array • AC/DC Adapter • Connect load • AC inverter • 12VDC Device • Light weight • Efficient • MPS also valid in consumer market PLANNING REQUIREMENTS FR-01 Solar panel input – 1.2A @ 5.4V (20W) Amorphous Silicon Panel FR-02 100W minimum Lithium-Ion battery capacity FR-03 15V DC input (with AC-DC Adapter) FR-04 12V DC output FR-05 Operation in temperature range of -20°C and 60°C FR-06 State of charge indicator FR-07 Charge Balancing Circuitry to keep Li-Ion Batteries balanced FR-08 Achieve 80% or greater efficiency NFR-01 MPS should have a weight of less than 5 pounds NFR-02 MPS should be manufactured for a cost of under $500 per unit NFR-03 MPS should easily fit inside a military backpack DELIVERABLES • • • MPS prototype PCB with Li-ion batteries MPS poster MPS Final Report PLANNING SCHEDULE PLANNING RESOURCES AND RISKS • • • • • Adequate lab space provided for development TI Analog Design Contest • Free analog evaluation modules PCB fabrication and parts • ECpE Parts Shop • PowerFilm, Inc. Knowledge resources • Dr. Fayed • PowerFilm • Brad Scandrett • Frank Jeffrey Risks • Short circuit • Li-ion overcharge • Unavailable parts DESIGN SYSTEM DECOMPOSITION Solar Panel Source Buck Converter Voltage and Current Sense PWM Control Signal Microprocessor (MSP430) Serial Communication (UART) to PC Feedback Voltage/Current Sense Li-ion Batteries (3 series cells x 8Ah) Charge Control (BQ20Z70) Possible Loads 5VDC (USB) 12VDC 120VAC DESIGN SYNCHRONOUS BUCK CONVERTER • • Synchronous rectification improves efficiency • Eliminates voltage drop across safety diode D1 Controlled by FET driver IR2104 DESIGN PSPICE SIMULATION • • • Functionality Testing Parasitic inductance DESIGN MPPT & LI-ION CHARGING Solar I-V Curve Li-Ion Charge Cycle DESIGN MSP430 MICROPROCESSOR DESIGN , HIGH SIDE CURRENT SENSE DESIGN , LOW SIDE CURRENT SENSE DESIGN , VOLTAGE SENSE DESIGN GUI & MPS COMMUNICATION • UART Comm. (via USB) • Live reporting & plotting • Processing (Java) • All measured values • Voltages • Currents • Duty cycle • Charging state • Debugging tool • Demonstration tool DESIGN LI-ION BATTERY BALANCING •TEXAS INSTRUMENTS - BQ20Z70 •IMPEDANCE TRACK BALANCING ALGORITHM •BQ EVALUATION SOFTWARE INCLUDED IMPLEMENTATION & TESTING BREADBOARD • Test functionality of buck converter • Used signal generator for PWM (100 kHz) • Successfully bucks DC voltage • Varying duty cycle • Connected buck converter and MSP430 • MSP430 controls duty cycle • Reset problem • Breadboard adapters used for ICs IMPLEMENTATION & TESTING BREADBOARD TESTING • Voltage transients • Parasitic Inductance • MOSFET Switching • Snubber RC filter • GROUNDING! • Transients caused inaccurate voltage/current readings • Fought issues for three weeks • Solution? • Design and fabricate PCB with large grounding plane IMPLEMENTATION & TESTING PCB REV. 1 • • • • Designed with EagleCAD • No solder mask for mods. Transient voltage problem fixed with ground plane! • Accurate voltage and current readings • Used low-ESR components • Surface-mounting components eliminates noise Problem with differential amplifier used for measuring high-side current • Insufficient common-mode voltage input range Solution? • Differential amplifier with rail-to-rail common-mode voltage input. • PCB Rev. 2 IMPLEMENTATION & TESTING PCB REV. 2 • PCB Changes: • Updated high-side current sense differential amplifier. • Zener diode protection • Solder mask • One connector for both programming and UART • Resume calibration and testing IMPLEMENTATION & TESTING CALIBRATION • Sweep duty cycle range and record serial data for: • Solar input voltage and current • Battery voltage and current • Load current (30Ω load resistor) • Import data to excel and run macro to take linear regression and convert serial data to actual voltage and current readings. IMPLEMENTATION & TESTING TESTING • Start with power supply: • Constant V & I • Variable V & I • Monitor output V & I • Measure efficiency • Practice charging algorithm on lead-acid battery (more forgiving) • Trickle charge if pack voltage is less than 9V • Constant current mode (≤ 500mA) & MPPT • Constant voltage mode (12.6V) • Shut down if: • Battery pack current (≤ 100mA) • AND Load current (≤ 100mA) IMPLEMENTATION & TESTING TESTING (CONT’D) • Connect PowerFilm Solar array • Power solar array and tested on few sunny days • Fine tuned MPPT algorithm • Verified all charging states • Connect Li-ion battery • Charged pack using MPS • Monitor cell balancing with TI software and MPS GUI • Power external load • Warmed resistors • LED lamp • Laptop through inverter FINAL REMARKS CONCLUSION • • • Many lessons learned Technical • Breadboards are terrible for certain circuits. Use only to test functionality. • PCBs, surface mount components, and large ground plane help transient and noise problems. • Never assume parts will work as planned. • GUIs and Macros are tools that make life easier. Management • Utilize talents. • Stick to schedule. • Establish ambitious goals. • Take lots of picture and screen shots. • Documentation is just as important as the product. MOBILE POWER STATION Thank You: • Dr. Ayman Fayed • Brad Scandrett • Frank Jeffrey • Dr. Daji Qiao • CSG • PowerFilm Inc. • ECpE Faculty & Staff • Texas Instruments • C2 Development
