Project Assignment #1 Aerodynamic Analysis of the BWB Wind Tunnel Model Sample Solution Prof. David L. Darmofal Department of Aeronautics and Astronautics Massachusetts Institute of Technology September 29, 2005 1 Data Table 1 contains geometric data for the full-scale BWB. Table 2 contains data for the wind tunnel. For now, assume that the air is at standard sea level conditions (i.e. the temperature, density, pressure, and viscosity) in the wind tunnel test section. Symbol Sref Swet b cmac Parameter Reference Area (trapezoidal wing) Wetted Area Wing span Mean aerodynamic chord Value 7,840 ft 2 31,324 ft2 280 ft 30.75 ft Table 1: Geometric data for full-scale BWB Symbol U� �� a� q� Parameter Model scale freestream velocity freestream density freestream kinemativ viscosity freestream speed of sound freestream dynamic pressure Value 1/47 50 and 100 mph 0.00237 sl/ft3 1.58e-04 ft 2 /s 1116.4 ft/s 25.56 lb/ft 2 Table 2: Wind tunnel data 2 Aerodynamic Model To estimate the aerodynamic forces and moment on the BWB in the tunnel, a vortex lattice calculation is combined with a semi-empirical estimate of the skin friction and pressure drag (C D f and CDp , respectively). The vortex lattice calculation provides estimates for the lift coeﬃcient (CL ), the induced drag coeﬃcient (CDi ), and the pitching moment coeﬃcient about the aircraft nose (CM 0 ). The total drag is the sum of the three drag estimates, Note, since the wind tunnel test is at subsonic conditions, wave drag is not expected to occur. 1 3 Required Tasks 3.1 Mach and Reynolds Number for Wind Tunnel Tests The Reynolds number reported here is based the mean aerodynamic chord, i.e., U� cmac Rec = . �� Note that the value of cmac is 1/47 of the value listed in Table 1 because of the scale of the wind tunnel model. For the 50 and 100 mph tunel speeds, the Mach and Reynolds number are given in Table 3. U� 50 mph 100 mph M� 0.065 0.130 Rec 3.03e5 6.06e5 Table 3: Freestream Mach and Reynolds number for tunnel tests. 3.2 Description of Friction and Pressure Drag Estimation The skin friction and pressure drag are estimated using the approach described in the Lift & Drag Primer. Speciﬁcally, for the friction drag, Swet . CDf � cf Sref The estimate of the average skin-friction coeﬃcient will be based on turbulent ﬂat plate data at a representative Reynolds number. For this purpose, we will use the ﬂat plate data in Figure 1 in the Lift & Drag Primer. As speciﬁed in the assignment, we assume that the boundary layer is turbulent and use the analytic equation given in Figure 1 to determine the skin friction coeﬃcient, 0.37 cf = . (1) (log10 Re)2.6 We will assume that the average skin friction c f can be estimated from Equation (1) using the Reynolds number based on the mean aerodynamic chord, Re c , i.e. 0.37 cf = . (log 10 Rec )2.6 At the two tunnel conditions, this gives, At 50 mph, CD f = 0.0177, At 100 mph, CD f = 0.0154. Following the Lift & Drag primer, the pressure drag coeﬃcient can be estimated as, � CDp = (CDp )min + CDf + CDp (CDp )min = 60 � tmax c �4 CDf . min CL 2 , However, since the BWB is relatively thin, the minimum pressure drag is expected to be small compared the skin friction. For example, if the maximum thickness-to-chord ratio were 20%, then (CDp )min � 0.1CD f . Thus, the minimum pressure drag is about 10% of the skin friction drag and therefore will be neglected. As a result, the pressure drag estimate reduces to, CDp � CDf CL 2 . 2 3.3 Plots The vortex lattice code, AVL, was run at a series of angles for both Mach numbers. The aero dynamic data from the AVL simulations is shown in Table 4 and 5. This data was then used to produce the required plots. Note, the neutral point which is reported by AVL is the distance in feet from the nose of aircraft at fullscale. This location is normalized by the fullscale c mac = 30.75 feet and reported in the tables. As can be seen from the tables, there is very little diﬀerence in the inviscid predictions from AVL due to the change in Mach number. � -3 -2 -1 0 1 2 3 6 9 12 15 CL -0.152 -0.033 0.087 0.206 0.326 0.445 0.565 0.921 1.276 1.626 1.973 CDi 0.0017 0.0013 0.0019 0.0034 0.0058 0.0092 0.0136 0.0323 0.0591 0.0940 0.1364 CM 0 0.335 0.013 -0.310 -0.634 -0.958 -1.281 -1.604 -2.564 -3.505 -4.415 -5.284 xac /cmac 2.69 2.70 2.70 2.71 2.71 2.71 2.71 2.70 2.68 2.64 2.59 Table 4: AVL results for 50 mph (M� = 0.065). � -3 -2 -1 0 1 2 3 6 9 12 15 CL -0.153 -0.033 0.087 0.207 0.327 0.447 0.567 0.925 1.280 1.632 1.980 CD i 0.0017 0.0013 0.0019 0.0034 0.0059 0.0093 0.0137 0.0324 0.0595 0.0945 0.1372 CM 0 0.336 0.012 -0.312 -0.637 -0.962 -1.287 -1.611 -2.575 -3.519 -4.432 -5.305 xac /cmac 2.69 2.70 2.70 2.71 2.71 2.71 2.71 2.70 2.68 2.64 2.59 Table 5: AVL results for 100 mph (M� = 0.130). The required plots are shown in Figure 1-4; both tunnel speeds are included in each plot. However, for everything except the drag polar (Figure 2), the curves overlap. 3.4 Questions 1. How did the change in velocity impact the force and moment coeﬃcients? Answer: the coeﬃcients were almost unchanged by the velocity change except for a small dependence of the CD . The dependence of CD on the velocity arises from the change in the friction drag estimate which is a function of the Reynolds number. 3 2 1.5 C L 1 0.5 0 −0.5 −4 −2 0 2 4 6 � 8 10 12 14 16 Figure 1: CL versus � for 50 (blue) and 100 (red) mph. 2 1.5 C L 1 0.5 0 −0.5 0 0.05 0.1 C 0.15 0.2 0.25 D Figure 2: CL versus CD for 50 (blue) and 100 (red) mph. 4 0.2 0.15 0.1 Mac 0.05 C 0 −0.05 −0.1 −0.15 −0.2 −0.5 0 0.5 C 1 1.5 2 L Figure 3: CM ac versus CL for 50 (blue) and 100 (red) mph. 4 3.5 x /c cp mac , x /c ac mac 3 2.5 2 1.5 1 0.5 0 −0.5 0 0.5 C 1 1.5 2 L Figure 4: xcp (solid) and xac (dashed) versus CL for 50 (blue) and 100 (red) mph. 5 2. Given the response to the previous question, what will the impact of the changing the velocity by a factor of two have on the force and moments (i.e. not the force and moment coeﬃcients)? Answer: Given that the force and moment coeﬃcients are relatively unchanged by the velocity in the tunnel, the force and moments are expected to increase by a factor of 4 for a factor 2 increase in the velocity. For example, the lift is related to the lift coeﬃcient by, L = q� Sref CL . 2 and C was insensitive to the velocity change, then L V 2 which results in Since q� V� L � the lift having a squared dependence on the velocity. 6