Wing-tail configuration

Example simulation of a fixed-wing configuration
The wing-tail configuration has a wing aspect ratio AR=10AR=10AR=10
, wing area Sref=0.3S_{ref}=0.3Sref​=0.3
m2^22
, wing chord cref=0.1732c_{ref}=0.1732cref​=0.1732
m. Both the wing and the tail have a taper ratio of 1. The distance between the quarter-chord points of the wing and the tail is l=0.56l=0.56l=0.56
m. A body-fixed coordinate system is placed at the wing quarter-chord point. The reference speed is ∣Vref∣=25|\mathbf{V}_{ref}|=25∣Vref​∣=25
m/s and the reference density, pressure, and viscosity are evaluated at an altitude of h=0h=0h=0
m (ISA). An unstructured mesh with 6354 panels is used. The image below shows the pressure coefficient of the wing-tail configuration at an angle of attack α=5\alpha=5α=5
deg.
Wing-tail configuration pressure coefficient 
The lift, drag and pitching moment coefficients of the wing-tail configuration are assumed to be given by:
CX=CX0+CX,αα+CX,qˉqˉ+CX,δeδeCZ=CZ0+CZ,αα+CZ,qˉqˉ+CZ,δeδeCm=Cm0+Cm,αα+Cm,qˉqˉ+Cm,δeδe,C_{X}=C_{X0}+C_{X,\alpha}\alpha+C_{X,\bar{q}}\bar{q}+C_{X,\delta_{e}}\delta_{e}\\ C_{Z}=C_{Z0}+C_{Z,\alpha}\alpha+C_{Z,\bar{q}}\bar{q}+C_{Z,\delta_{e}}\delta_{e}\\C_{m}=C_{m0}+C_{m,\alpha}\alpha+C_{m,\bar{q}}\bar{q}+C_{m,\delta_{e}}\delta_{e} \text{,}
CX​=CX0​+CX,α​α+CX,qˉ​​qˉ​+CX,δe​​δe​CZ​=CZ0​+CZ,α​α+CZ,qˉ​​qˉ​+CZ,δe​​δe​Cm​=Cm0​+Cm,α​α+Cm,qˉ​​qˉ​+Cm,δe​​δe​,
where qˉ=qcref2Vref\bar{q}=\frac{qc_{ref}}{2V_{ref}}qˉ​=2Vref​qcref​​
 is the normalised pitch rate. The CXC_{X}CX​
, CZC_{Z}CZ​
, and CmC_{m}Cm​
 are functions of the the angle of attack α\alphaα
, the normalised pitch rate qˉ\bar{q}qˉ​
 and the elevator deflection angle δe\delta_{e}δe​
. The aim is to obtain the CX0C_{X0}CX0​
, CZ0C_{Z0}CZ0​
, and Cm0C_{m0}Cm0​
 coefficients and the CX,αC_{X,\alpha}CX,α​
, CX,qˉC_{X,\bar{q}}CX,qˉ​​
 , CX,δeC_{X,\delta_{e}}CX,δe​​
, CZ,αC_{Z,\alpha}CZ,α​
, CZ,qˉC_{Z,\bar{q}}CZ,qˉ​​
, CZ,δeC_{Z,\delta{e}}CZ,δe​
, Cm,αC_{m,\alpha}Cm,α​
, Cm,qˉC_{m,\bar{q}}Cm,qˉ​​
, and Cm,δeC_{m,\delta_{e}}Cm,δe​​
 derivatives using APM.
Obtaining the 0-coefficients
A simulation of the wing-tail configuration is performed at α=0\alpha=0α=0
 rad, p=0p=0p=0
 rad/s, δe=0\delta_{e}=0δe​=0
 rad. The values for the aerodynamic coefficients are recorded. They are the values of the 000
- coefficients.
Obtaining the angle of attack and elevator deflection derivatives
As already discussed, a simulation of the wing-tail configuration is performed at α=0\alpha=0α=0
rad, p=0p=0p=0
 rad/s, δe=0\delta_{e}=0δe​=0
rad. The values for the aerodynamic coefficients are recorded. A second simulation of the wing-tail configuration is performed at α=0.1\alpha=0.1α=0.1
 rad, p=0p=0p=0
rad/s, δe=0\delta_{e}=0δe​=0
 rad. The choice of value for α\alphaα
 is arbitrary. Again the aerodynamic coefficients are recorded. To obtain the α\alphaα
- derivatives a simple difference is used:
CZ,α=CZ∣α=0.1−CZ∣α=0Δα,C_{Z,\alpha}=\frac{C_{Z}\rvert_{\alpha=0.1}-C_{Z}\rvert_{\alpha=0}}{\Delta\alpha}\text{,}CZ,α​=ΔαCZ​∣α=0.1​−CZ​∣α=0​​,
where Δα=0.1\Delta\alpha=0.1Δα=0.1
rad. The same method is used to obtain the δe\delta_{e}δe​
- derivatives.
Obtaining the pitch rate derivatives
The coordinate system used for the analysis above is fixed to the wing quarter-chord point however, this point does not coincide with the centre of gravity. If one determines the qˉ\bar{q}qˉ​
- derivatives with respect to this coordinate system they will not be representative of the qˉ\bar{q}qˉ​
- derivatives with respect to the centre of gravity. To determine the position of the centre of gravity (often driven by a required static margin), the neutral point position must be found. By definition, the stick-fixed neutral point position is where:
Cm,α=0.C_{m,\alpha}=0\text{.}Cm,α​=0.
Using the difference method described above, the value of Cm,αC_{m,\alpha}Cm,α​
 is obtained for two different locations of the centre of gravity. The first location is when the centre of gravity coincides with the quarter-chord point of the wing xcg=0x_{cg}=0xcg​=0
m and the second location is selected forward of the quarter-chord point of the wing xcg=0.05x_{cg}=0.05xcg​=0.05
m. The choice of value for xcgx_{cg}xcg​
 is arbitrary. The equation for Cm,αC_{m,\alpha}Cm,α​
 as a function of xcgx_{cg}xcg​
 is then:
Cm,α=axcg+b−2.0012=a0+b−3.5526=a0.05+ba=−31.028b=−2.0012. C_{m,\alpha}=ax_{cg}+b\\
                 -2.0012=a0+b \\
                 -3.5526=a0.05+b \\
                a=-31.028 \\
                 b=-2.0012 \text{.}Cm,α​=axcg​+b−2.0012=a0+b−3.5526=a0.05+ba=−31.028b=−2.0012.
The solution of the equation gives xcg=−0.0645x_{cg}=-0.0645xcg​=−0.0645
, for Cm,α=0C_{m,\alpha}=0Cm,α​=0
. This is the location of the stick-fixed neutral point, xnpx_{np}xnp​
, (xnpx_{np}xnp​
=xcgx_{cg}xcg​
 for Cm,α=0C_{m,\alpha}=0Cm,α​=0
). The centre of gravity location for a 15% static margin is then given by:
SM=0.15=xcg−xnpcrefxcg∣SM=0.1=xnp+0.15cref,SM=0.15=\frac{x_{cg}-x_{np}}{c_{ref}}\\
              x_{cg}\rvert_{SM=0.1}=x_{np}+0.15c_{ref} \text{,}SM=0.15=cref​xcg​−xnp​​xcg​∣SM=0.1​=xnp​+0.15cref​,
with xcg=−0.03852x_{cg}=-0.03852xcg​=−0.03852
m. The qˉ\bar{q}qˉ​
- derivatives can now be obtained with respect to this point. A forced sinusoidal motion is imposed on the wing-tail combination:
α=Asin(ωt)ω=2πf,\alpha=Asin(\omega t) \\
 \omega=2\pi f\text{,}α=Asin(ωt)ω=2πf,
where A=5A=5A=5
deg is the amplitude of the motion and f=5f=5f=5
Hz is the frequency of the motion. The video below shows the development of the wing-tail configuration wake during the forced sinusoidal motion.
Wing-tail configuration wake development
The values of CmC_{m}Cm​
 with respect to α\alphaα
 make a quasi-steady elliptical hysteresis. Two points exist at which the angular velocity is maximum or minimum. Cm,qˉC_{m,\bar{q}}Cm,qˉ​​
 derivative is estimated from the values of the CmC_{m}Cm​
 at these points
Cm,qˉ=Cm∣qmax−Cm∣qmin2kA,k=ωcref2Vref,C_{m,\bar{q}}=\frac{C_{m}\rvert_{q_{max}}-C_{m}\rvert_{q_{min}}}{2kA},\\
k=\frac{\omega c_{ref}}{2V_{ref}}\text{,}
Cm,qˉ​​=2kACm​∣qmax​​−Cm​∣qmin​​​,k=2Vref​ωcref​​,
where kkk
 is the reduced frequency. The same method is used to obtain the other qˉ\bar{q}qˉ​
- derivatives. Below are the wing-tail configuration derivatives estimated by the method.
​
​0_{0}0​
​
​∂∂α\frac{\partial}{\partial \alpha}∂α∂​
​
​∂∂qˉ\frac{\partial}{\partial \bar{q}}∂qˉ​∂​
​
​∂∂δe\frac{\partial}{\partial \delta_{e}}∂δe​∂​
​
​CXC_{X}CX​
​
-0.0114
0.2555
-0.2491
-0.0195
​CZC_{Z}CZ​
​
-0.3219
-5.1439
2.7170
-0.8377
​CmC_{m}Cm​
​
0.0556
-0.9575
-20.0581
-2.3205
Files
wing_tail_configuration.zip
375KB
Binary
​
AGARD-AR-303 E6
Fixed-wing UAV
Last modified 1yr ago
	$_{0}$	$\frac{\partial}{\partial \alpha}$	$\frac{\partial}{\partial \bar{q}}$	$\frac{\partial}{\partial \delta_{e}}$
$C_{X}$	-0.0114	0.2555	-0.2491	-0.0195
$C_{Z}$	-0.3219	-5.1439	2.7170	-0.8377
$C_{m}$	0.0556	-0.9575	-20.0581	-2.3205