The document discusses the development of an airborne SiC inverter capable of operating at high temperatures up to 200°C. It summarizes the characterization of SiC JFETs which retain many properties at high temperatures but have increased losses. A gate driver circuit for the JFETs is presented along with initial testing of a 3 phase inverter showing it can operate at 250°C and 15A peak current. While the inverter core and a "cold" gate driver have been demonstrated, further testing is still needed to verify the full high temperature performance and reliability over long time periods and thermal cycling.
Powerpoint exploring the locations used in television show Time Clash
toward high temperature power converters
1. Towards an airborne high temperature SiC inverter
Ampère CNRS UMR 5005
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Dominique Bergogne, Hervé Morel,
Dominique Planson, Dominique Tournier,
Pascal Bevilacqua, Bruno Allard
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Hispano-Suiza SAFRAN group
Régis Meuret, Sébastien Vieillard
Dominique Bergogne (Ampere-lab) PESC’08-Rhodes, June 2008 1 / 28
3. More Electrical Aircraft
1 More Electrical Aircraft
2 Characterizations
3 JFET gate driver
4 Experimental verification
5 Conclusion
Dominique Bergogne (Ampere-lab) PESC’08-Rhodes, June 2008 3 / 28
4. More Electrical Aircraft
Final target
+ 2 years
Controler + gate driver + inverter up to 200°C
Now : step One
control + driver : 25°C
inverter : 200°C
Dominique Bergogne (Ampere-lab) PESC’08-Rhodes, June 2008 4 / 28
5. More Electrical Aircraft
A severe environment
Dominique Bergogne (Ampere-lab) PESC’08-Rhodes, June 2008 5 / 28
6. More Electrical Aircraft
Specifications
Stand-by 50 000 hours*
Operation < 1000 hours
Thermal cycles 15000
Thermal cycle -55°C to 200°C
Power range 1-50 kW*
DC input +/- 270V
AC output 230V
Cooling temperature up to 200°C
At now
540VDC
6ARMS per phase
cooling temperature : 200°C
Dominique Bergogne (Ampere-lab) PESC’08-Rhodes, June 2008 6 / 28
7. More Electrical Aircraft
Why SiC JFETs ?
Thermal runaway physical limits. SiC limits do not fit within this plot
Dominique Bergogne (Ampere-lab) PESC’08-Rhodes, June 2008 7 / 28
10. Characterizations
Effect of temperature : JFET static
Measured at 225°C on one sample JFET*
Saturation current is reduced at high temperature
from 40A at 25°C to 25A at 225°C for this sample device
RDSON varies from 0.2Ω to 0.6Ω
Dominique Bergogne (Ampere-lab) PESC’08-Rhodes, June 2008 10 / 28
11. Characterizations
Effect of temperature : JFET dynamic
Power side
Turn-Off losses are almost constant versus temperature
Turn-On losses are reduced from 900uJ to 500uJ
Control side
Gate charge is not affected by temperature
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12. Characterizations
Effect of temperature : inductance
Inductance is not affected, but losses ...
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13. Characterizations
Effect of temperature : capacitor
Capacitance is reduced , series resistance increases (ceramic)
by a factor of 3
Dominique Bergogne (Ampere-lab) PESC’08-Rhodes, June 2008 13 / 28
14. Characterizations
Effect of temperature
Conclusion
High Temperature requires specific components/materials
Some characteristics remain constant while ...
Losses, in general, are increased at high temperature (times 10)
Dominique Bergogne (Ampere-lab) PESC’08-Rhodes, June 2008 14 / 28
16. JFET gate driver
What do we want ?
Fast gate transients for reduced dynamic losses on the power side
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17. JFET gate driver
Driver requirements
Set by JFET (4mm², 1200V)
Maximum gate voltage : -30V
Peak current : 0.5 to 1A
Set by environment
Insulation up to 1000V, high dv/dt
Logic signal input
Several protections
High temperature
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19. JFET gate driver
Normal temperature driver
The driver’s fonctions are implemented in a ’cold’ prototype
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20. JFET gate driver
High temperature driver bloc diagram
This driver is compatible with high temperature.
Currently ’under construction’
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25. Experimental verification
Verification
Verified
Driver and inverter functions
Electrical behaviour of inverter at high temperature
To be Verified
Power losses (calorimetric/thermal measurement)
Electrical behaviour of the system over full temperature range
Thermal cycling mechanical stress effects
Dominique Bergogne (Ampere-lab) PESC’08-Rhodes, June 2008 25 / 28
27. Conclusion
Conclusion
What is functionnal ?
Inverter power core functionnal
’Cold’ Driver
To be continued
High temperature driver
Thermal range testing of the system
Mechanical aspects, integration
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28. Conclusion
Thank you for your attention.
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