+
DC – DC Converter For a Thermoelectric Generator
Ciaran Feeney4th Electronic Engineering StudentFYP Progress Presentation
Supervisor: Dr. Maeve Duffy
Stove TEG
DC-DCConverter Battery
+Presentation Overview
Project overview Progress to date Future work and timeline Questions
+Project Overview
Researchers in Trinity College Dublin are developing a energy harvesting system for use in developing countries.
Generate electricity using a Thermoelectric Generator(TEG) from excess heat produced during the cooking process.
Store energy generated in a battery Use stored power in low power applications This project focuses on providing an impedance match
between the source and load using a DC-DC Converter and Microcontroller
+System Block Diagram
TEGStove
DC – DC Converter
Battery
Pack
Microcontroller
+Progress To Date
Thermoelectric generator operation understood Battery charge and discharge profile established DC-DC converter Topology determined Basic analysis of 1st SEPIC DC-DC converter circuit
complete Suitable Microcontroller found Website online and blog regularly updated
+Thermoelectric Generator
Single Thermoelectric Couple Full Thermoelectric Generator
+Thermoelectric Generator
+Thermoelectric Generator
Equivalent TEG Circuit Model
+Battery Charge and Discharge Profiles
0 10 20 30 40 50 60 70 802.42.52.62.72.82.9
33.13.23.33.43.53.63.7
Voltage increase with constant current 2A
Vbatt
TIme(mins)
Voltg
e ac
ross
BAt
tery
+Battery Charge and Discharge Profiles
0 20 40 60 80 100 120 140 160 180 2002.42.52.62.72.82.9
33.13.23.33.4
Discharge Through 3.3ohm LoadApprox Vload = 2.5Approx Iload = .8
Vbatt
Time (mins)
Volta
ge
+DC-DC Converter
Require DC-DC converter that can provide an output voltage above and below input voltage
Variation of Buck Boost topology decided upon SEPIC DC-DC Converter
Non-inverting output Isolation between output and input terminals due to
coupling capacitor
+DC-DC Converter
SEPIC Topology
SEPIC Converter 1st Prototype Chosen Components
+DC-DC Converter
Input Voltage 4VMatched Voltage 2VOutput Voltage .846V Duty Cycle 41.8%Efficiency 71.4%Resistive Load
+DC-DC Converter
0 2 4 6 8 10 12505254565860626466687072747678808284868890
Efficiency
"Efficiency"
Input Voltage
Effiic
ienc
y %
+DC-DC Converter
Redesigned SEPIC Converter Switching frequency is now 80kHz
Reduces size of components Reduces cost
Diode Replaced by MOSFET Circuit Components
Inductor Coupled 16uH 10A Wureth .0027ohm €5.83MOSFET NXP MOSFET Power 30V 98A N-CH MOSFETs €0.82MOSFET NXP MOSFET Power 30V 98A N-CH MOSFETs €0.82Coupling Capacitor Aluminum Organic Polymer Capacitors 16V 100uF 7Mohms €0.561Input Capacitor Aluminum Organic Polymer Capacitors 16V 100uF 7Mohms €0.561Output Capacitor Aluminum Organic Polymer Capacitors 16V 100uF 7Mohms €0.561
+DC-DC Converter
New Design Replacing diode with MOSFET Design includes Equivalent Series Resistances for
components
+Microcontroller
Required characteristics PWM (Pulse Width Modulation) Analog Input pins Low power consumption Low cost Easily programmable
Chosen Controller – Arduino Uno Fulfills all of the above criteria Cost €24.31 Abundance of information available online
+Future Work
MPPT Initial Investigation shows that load current should be
maximized as the battery can be viewed as a purely voltage source.
Preliminary investigation into current sensors reveals that a hall effect sensor should be used instead of a current sense resistor.
Sensor to be placed in series with battery A hall effect sensor has been singled out for further
investigation The Allegro Microsystems Current Sensor Rated for 5A Low series resistance 1.2mΩ Cost low €6.54 185mV per Amp
+Future Work
Charge Algorithm Constant current to 3.6V Constant voltage of 3.6V until charge cut off current is
reached or 30 minutes has elapsed Voltage to be monitored across battery
Yet to be decided whether a constant voltage will be applied Researchers in Trinity College Dublin to decide this
+Future Work
Implementation of Circuit with Thermoelectric Generator Microcontroller implementing MPPT Simulated cooking profile/Actual cooking duration Battery
Efficiency analysis over cooking profile Identify were improvements can be made
+Timeline
Efficiency Analysis
1st Draft of Mock Circuit Analysed and Deficiencies located. Circuit Optimised to minimise deficiencies.
16th of January 2011
MPPT & ChargeAlgorithm MPPT & Charge Algorithm decided upon and completed.
14th of February 2011
Final Circuit and Testing
Finished circuit completed incorporating MPPT and charge algorithm. Circuitry tested over full charge and discharge cycle with TEG and battery.7th of March 2011
Bench DemonstrationFinal ThesisWeek of the
14th of March 2011 1st of April
2011
+Questions