Zeitschriftenartikel:
D. Samson, M. Kluge, T. Fuss, U. Schmid, Th. Becker:
"Flight Test Results of a Thermoelectric Energy Harvester for Aircraft";
Journal of Electronic Materials,
41
(2012),
6;
S. 1134
- 1137.
Kurzfassung deutsch:
The idea of thermoelectric energy harvesting for low-power wireless sensor systems in aircraft
and its practical implementation was recently published. The concept of using a thermoelectric
generator (TEG) attached to the aircraft inner hull and a thermal storage device to create an
artificial temperature gradient at the TEG during take-off and landing from the temperature
changes of the fuselage has passed initial tests and is now subject to flight testing. This work
presents preflight test results, e.g., vibration and temperature testing of the harvesters, the
practical installation of two harvesting devices inside a test plane, and the first test flight results.
Several flight cycles with different flight profiles, flight lengths, and outside temperatures have
been performed. Although the influence of different flight profiles on the energy output of the
harvester can be clearly observed, the results are in good agreement with expectations from
numerical simulations with boundary conditions evaluated from initial climate chamber
experiments. In addition, the flight test demonstrates that reliable operation of thermoelectric
energy harvesting in harsh aircraft environments seems to be feasible, therefore paving the way
for realization of energy-autonomous, wireless sensor networks.
Kurzfassung englisch:
The idea of thermoelectric energy harvesting for low-power wireless sensor systems in aircraft
and its practical implementation was recently published. The concept of using a thermoelectric
generator (TEG) attached to the aircraft inner hull and a thermal storage device to create an
artificial temperature gradient at the TEG during take-off and landing from the temperature
changes of the fuselage has passed initial tests and is now subject to flight testing. This work
presents preflight test results, e.g., vibration and temperature testing of the harvesters, the
practical installation of two harvesting devices inside a test plane, and the first test flight results.
Several flight cycles with different flight profiles, flight lengths, and outside temperatures have
been performed. Although the influence of different flight profiles on the energy output of the
harvester can be clearly observed, the results are in good agreement with expectations from
numerical simulations with boundary conditions evaluated from initial climate chamber
experiments. In addition, the flight test demonstrates that reliable operation of thermoelectric
energy harvesting in harsh aircraft environments seems to be feasible, therefore paving the way
for realization of energy-autonomous, wireless sensor networks.
"Offizielle" elektronische Version der Publikation (entsprechend ihrem Digital Object Identifier - DOI)
http://dx.doi.org/10.1007/s11664-012-1928-6
Erstellt aus der Publikationsdatenbank der Technischen Universität Wien.