Efficient Electromagnetic Analysis and Design Techniques in Jet Engines
الملخص
A statistical electromagnetics based approach is proposed for efficient analysis
of electromagnetic propagation inside harsh environments, like jet engines,
to establish a communication channel inside the environment. The study of
electromagnetic propagation inside the jet engine compressors that are close
to turbine blades faces several difficulties due to the design complexity. The
jet engine environment is an extremely complex geometry and exhibits random
behavior due to the presence of moving metallic parts. The complex geometry
environment combined with the inhomogeneous volumetric target render traditional
analytical and simulation modeling techniques highly inefficient. To
address this issue, two different approaches are proposed. The first is an innovative
dynamic simulation approach based on statistical electromagnetic methods
and inspired by analysis of mechanically stirred reverberation chambers.A
dimension scaling method is introduced along with the dynamic simulation approach
to solve the complex jet engine environment. Furthermore, the effect of
excitation on the field characteristics of the dynamic system has been analyzed
to prove that the dynamic system is statistically linear.
In the second approach, a novel statistical excitation method is applied to
develop an equivalent model for the fields generated by a fixed excitation inside
a jet engine with dynamic rotating blade. Hence, the jet engine is considered
as a static system without blade rotation, but with a random excitation. The
dynamic and static systems have been compared using full wave simulation
method and numerical methods. The results proved that there is a statistical equivalence between the dynamic and the static systems. The effect of the
Doppler frequency shift on the electric field strength inside a jet engine is
analyzed by using a stepwise stationary blade rotation method. The results
show that the amplitude deviation due to frequency shift is negligible at all
receiving probe locations. Later, the effect of blade rotation on the electric
field phase variation is also analyzed. The results are very promising for the
future modeling of the jet engine Doppler shift in terms of field phase time
variation.
A new low profile microstrip antenna array is proposed and analyzed for
wireless sensor applications in extremely harsh jet engine environments. This
design is to establish a communication link between the wireless sensors inside
the jet engine with the receiving antennas and hence the entire system
is designed for ISM band of frequency. Due to the environmental constraints,
the antenna is designed to be extremely thin and flexible. The proposed antenna
is designed to have a canonical beam pattern. Three different models
of patch antenna arrays, circular, half circular, and hybrid rectangular circular
models are designed, simulated, fabricated and experimentally measured. The
proposed antennas radiate symmetrically around the normal axis Z, with a
null in the boresight direction. The radiation pattern of the proposed antenna
is promising for real-time applications inside a jet engine since the strongest
radiation field of the antenna is pointed towards the engine blades.
DOI/handle
http://hdl.handle.net/10576/11217المجموعات
- الهندسة الكهربائية [53 items ]