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DESIGN, CONTROL AND IMPLEMENTATION OF INVERTERS TOPOLOGIES APPLIED TO DOMESTIC INDUCTION HEATING
Student: Peter Doyle
Supervisor: Prof. Gerard Hurley
Ignacio Lope
Final Year Project Presentation
Topics to be discussed:
• Function of Domestic Induction Heating Appliance
• Circuit Design and Analysis
• Digital Control
• Achieving Optimal Power Output
• Circuit Simulation
• Experimental Results
• Tasks to be completed
Function of Domestic Induction Heating Appliances
V
I
f = 50Hz
VdcVac
Iac
DC Bus f = 20 kHz – 100 kHz
Circuit Design and Analysis
Circuit Objectives:
• Maintain Zero voltage switching
• Generate a AC voltage
• Be able to produce a variable frequency 30kHz -
70kHz to control Power Output
Function of the Half-Bridge
Digital Control
• The Half-Bridge is controlled by an FPGA• The variable switching frequency is generated by the FPGA
from 70kHz - 30kHz depending on the required power output. • This signal is sent to the Signal Driver to improve the strength
of the signal at its source before it is transmitted to the transistors on the PCB. The Signal Driver has the logic inverse.
Digital Control
• After the FPGA was programmed it was discovered that when the FPGA is turned on the output of the pins went high for 1.8sec.
• The Solution was to add a relay circuit to isolate the PCB from mains voltage until intentionally switched on.
Achieving Optimal Power Output
10 14 18 22 26 30 34 38 42 46 50 54 58 62 66 70 74 78 82 86 90 94 980
1000
2000
3000
4000
5000
6000
Power v Frequency
1440nF500nF2500nF
Switching Frequency (kHz)
Po
we
r (W
)
• As shown in the graph below the resonant frequency, fr, (freq. at max power output) varies depending on the value of the resonant capacitor, Cr.
• The Switching frequency, fsw, must be greater than the resonant frequency to ensure Zero voltage switching.
Circuit Simulation
Experimental Results
Experimental Results
Load Current @ 70khz
Load Current @ 35kHz
Tasks to be Completed:
• Design a compete simulation of the Half-Bridge circuit including, filters, mains voltage rectification, switching topography and power output.
• Design of the printed circuit board (PCB) including choke, signal drivers, half bridge and common mode filter.
• Justify the selection of all component values. • Test the half bridge in small signal DC conditions. • Order PCB.• Test under mains voltage conditions and demonstrate using
existing control circuitry.
QUESTIONS?