Cart3D free-air simulation of D8

Transcription

Aerodynamic Evalua1on of the D8 "Double-‐Bubble" Aircra; Nacelle Design
Shishir Pandya, NASA Ames Research Center
Overset Grid Symposium, Dayton, OH, Oct 16, 2012
1
Outline
• The D8 – Concept
– Goals
• Modeling and Mesh Topology
– Use Cart3D inviscid mesh adapta1on to guide overset viscous mesh
– O-‐mesh with wake boxes
– Mesh sensi1vity
• Clean Configura1on
– Comparison with experiment
– Independent verifica1on of D8 concepts
• Podded Nacelle
– Geometry
– Results
2
MIT D8 “Double-‐Bubble” Aircra;
• MIT team concept of N+3 advanced vehicle configura1on
–Lower fuel burn
–Lower noise
–Reduce emissions
• 180 passengers
• 3000 nmi range
• 118 ; span
• ~Boeing 737 size
3
MIT/Pra] & Whitney/Aurora D Series
Airframe & Propulsion Technology Overview
Novel configura1on plus suite of airframe and propulsion technologies, and opera1ons modifica1ons
Reduced Secondary
Structure weight
Active Load
Alleviation
High Bypass Ratio Engines (BPR
20) with High-Efficiency Small
Cores
Boundary Layer
Ingestion
Health and
Usage
Monitoring
Distortion Tolerant
Fans
Tt4 Materials and
advanced cooling
Natural Laminar Flow
on Wing Bottom
Variable Area Nozzle
Lifting Body
Advanced Structural
Materials
Faired
Undercarriage
LDI Advanced
Combustor
Advanced Engine
Materials
Fuselage Advantages
• “Double-‐bubble” fuselage provides more li;
– Gives par1al span-‐wise loading / smaller wing
• Shorter cabin (wider body)
–Results in lighter landing gear support structure • Provides a nose-‐up pitching moment
–Shrinks horizontal tail
–Lighter horizontal tail
5
Lower Cruise Speed
• M=0.72
–Lower sweep wing
• Reduced structural load => Lower weight
• Increased CL
• Can eliminate high-‐li; devices
M. Drela, MIT
–Proper speed at engine fan face (M=0.6)
• Reduces nacelle, inlet size • Reduced nacelle drag
–Nacelles embedded in the π-‐tail and fuselage
–Reduced size, weight
6
Embedded Rear-‐Mounted Engines
• Boundary Layer Inges1ng (BLI) engines for Fans like flow at ~ M=0.6
propulsive efficiency
–Thicker boundary layer in the rear
–Designed for M=0.6 flow around engine inlet area
–Distor1on tolerant fan
–High bypass ra1o (~20)
• Lower engine-‐out yaw
–Reduced ver1cal tail size
Fan
• Noise shield
Nacelle
7
Wind Tunnel Tests
• Wright brothers wind tunnel at MIT
The Mach and Re don’t match
the flight, but the BLI effect is
not expected to be very
different
–Low speed (100 and 120 mph) ≈ M=0.15
–Clean configura1on: α=0, 1.9, 4.4, 6.6, 8.8, 11, 13.3
–Rec≈0.5 Million
–1:20 scale model
• Tests complete
–1:11 scale model
• Being constructed
• w/, w/o empennage
• Podded nacelle
• Blended nacelle
A. Uranga, MIT
8
Goals of This Work
• Independent assessment of the D8 design assump1ons
– Is the “double-‐bubble” fuselage advantageous?
• Does it provide li; in the range of 10 to 20%?
• Does it provide a nose-‐up pitching moment?
– Boundary Layer Inges1on (BLI)
• Quan1fy flow diffusion from fuselage geometry resul1ng in lower speed at the fan face
• Validate Overflow against the wind tunnel tests
– Use best prac1ces for nacelle assessment • Assess nacelle performance using Overflow
– Clean vs. Podded vs. Embedded
9
Simula1ons
• 120 mph (M=0.16)
• Alpha sweep: -‐2° to 14° in 2° increments
–Half-‐body cases (symmetry assumed)
• Steady, turbulent flow
• Clean configura1on
–in Free-‐air
–w/ WT
–w/ WT+mount/fairing
• Podded
• Embedded (geometry, mesh genera1on in progress)
10
Outline
• The D8
– Use Cart3D inviscid mesh adapta1on to guide overset viscous mesh
– O-‐mesh with wake boxes
– Mesh sensi1vity
• Podded Nacelle
11
Cart3D/Aero Solu1on Adap1ve Mesh
Original, 70K
• Component based inviscid solver
–Automated mesh genera1on, complex geometries
• Adjoint-‐based adap1ve mesh refinement used
–Takes place of a lot of user 1me and exper1se
3 adapts, 400K
6 adapts, 7M
9 adapts, 30M
12
Overflow
• Overset mesh genera1on follows
–Overset best prac1ces
–Guidance from Cart3D adap1ve refinement
• Finite difference
–Beam-‐Warming (approximate factoriza1on/central difference)
–Scalar dissipa1on
•
+
Turbulence model (SA, SST) with target y ≈1
13
Wake Grid with O-‐Grid Topology
• Eliminate C-‐ mesh
• Wake capture
• Tip vortex resolu1on
14
Rear WT core
Volume Mesh
WT mesh
19 near-‐body grids
1 WT grid
4 wake grids
9 box grids
2 core grids
35 total grids
Clean: ~80 Million Pts.
Podded: ~87 Million Pts.
Wake grids
Body-‐fi]ed grids
Front WT core
Box grids to cover test sec1on
15
Mesh Sensi1vity
• Test each parameter independently
–Wall spacing (y+)
–Near-‐wall stretching ra1o
–Surface spacing
• LE, TE, ...
–Off-‐body spacing
• Study done at α=0°
–SA turb. model 16
+
CL, CD Sensi1vity to y
D8 with WT walls and Strut, M=0.16, α=0 SR=1.15, DSs=1, DSo=0.15
0.45
D8, 1:20 scale model in WBWT with Mount, M=0.1578, α=0
15
10
CL
%CL
0.4
5
0.35
0.3
0
0
1
2
Y
0.040
+
3
4
5
74 M
78 M
80 M
82 M
Number of Points
84 M
86 M
35
0.038
76 M
30
0.036
25
0.034
CD
%CD
20
0.032
15
0.030
10
0.028
5
0.026
0.024
0
1
2
Y
+
3
4
5
0
74 M
76 M
78 M
80 M
82 M
Number of Points
84 M
86 M
17
CL, CD Sensi1vity to Surface Spacing
D8 with WT walls and Strut, M=0.16, α=0 0.45
15
y+=1, SR=1.15, DSo=0.15
10
CL
%CL
0.4
5
0.35
0.3
0
0
1
ΔSsurface
2
3
40 M
80 M
100 M
Number of Points
120 M
35
0.04
60 M
30
0.038
25
0.034
20
CD
%CD
0.036
0.032
0.03
15
10
0.028
5
0.026
0.024
0
1
ΔSsurface
2
3
0
40 M
60 M
80 M
100 M
Number of Points
120 M
18
CL, CD Sensi1vity to Stretching Ra1o
D8 with WT walls and Strut, M=0.16, α=0 0.45
15
y+=1, DSs=1, DSo=0.15
10
CL
%CL
0.4
5
0.35
0.3
1.05
0
1.1
1.15
1.2
Stretching Ratio
1.25
1.3
70 M
35
0.040
30
0.036
25
0.034
20
CD
%CD
0.038
0.032
0.030
80 M
Number of Points
90 M
100 M
15
10
0.028
5
0.026
0.024
1.05
1.1
1.15
1.2
Stretching Ratio
1.25
1.3
0
70 M
80 M
Number of Points
90 M
100 19
M
CL, CD Sensi1vity to Off-‐Body Spacing
0.45
D8 with WT walls and Strut, M=0.16, α=0 D8, 1:20 scale model in WBWT with Mount, M=0.1578, α=0
15
y+=1, SR=1.15, DSs=1
10
CL
%CL
0.4
5
0.35
0.3
0
0
0.1
0.2
Off-Body Grid Spacing
0.3
0.4
60 M
35
0.04
30
0.036
25
0.034
20
CD
%CD
0.038
0.032
0.03
80 M
100 M
Number of Points
120 M
140 M
15
10
0.028
5
0.026
0.024
0
0.1
0.2
Off-Body Grid Spacing
0.3
0.4
0
60 M
80 M
100 M
Number of Points
120 M
140 20
M
Produc1on Mesh
• Tested each parameter independently (α=0°, SA)
–Wall-‐normal spacing (tested 0.5 to 5)
• 0.00016 => y+ ≈ 1
–Stretching ra1o (tested 1.1 to 1.25)
• 1.15
–Surface spacing (tested LE spacing of 0.025 to 0.3%)
• LE spacing ≈ 0.006 (0.1% chord)
• TE spacing ≈ 0.003 (0.05% chord)
• Inboard airfoil covered by ~550 points
• Outboard airfoil covered by ~300 points
–Off-‐body spacing (tested 0.1 to 0.3)
• 0.15
21
Solu1on Consistency, Sensi1vity
• Pegasus vs. Xrays vs. c3Lib
–li; varies 2.9%, drag varies 1.1%
• AF vs. Diagonal vs. Roe vs. HLLC
–li; varies 3%, drag varies 1.4%
• Low-‐Mach pre-‐condi1oner
–No change in li; and drag
• Unsteady algorithm
–Flow remained steady with minor change in li; and drag • Various WT Inlet/Exit Boundary Condi1ons
–Minor varia1ons in integrated forces
22
Outline
• The D8 Concept/Goals
–Comparison with experiment
– Independent verifica1on of D8 concepts • Podded Nacelle
23
Convergence and Solu1on
Force/Moment History
Force/Moment History
1
Total Drag Coefficient
Total Lift Coefficient
0.15
0.5
0
0
10000
20000
Time Step Number
30000
40000
0.10
0.05
0.00
-0.05
0
10000
20000
Time Step Number
30000
40000
24
CL Comparison
2
WT
Cart3D
Overflow (SA)
Overflow(SST)
CL
1.5
1
0.5
0
0
5
α
10
15
25
CD Comparison
0.25
0.2
WT
Cart3D
Overflow (SA)
Overflow (SST)
CD
0.15
0.1
0.05
0
0
5
α
10
15
26
Span-‐wise Loading
Fuselage provides span loading
Pi-‐tail has minimum nega1ve loading
Y 27
Component-‐wise Break-‐down
CL
0.9
CD
Cm*
0.20
0.050
0.8
0.7
0.15
0.040
0.6
0.5
0.10
0.030
0.4
0.05
0.3
0.020
0
0.2
0.1
0.010
-0.05
0
-0.1
0
Total
Fuse. Wing Pi-tail
-0.10
Total Fuse. Wing Pi-tail
α=0
α=4
Total Fuse. Wing Pi-tail
*Fuselage provides a pitch-‐up moment
28
Boundary Layer Inges1on
Cruise condi1on, α=4°
29
Outline
• Podded nacelle
– Geometry
– Results
• Embedded nacelle
30
Podded Nacelle
• In free-‐stream
–Under-‐wing
–Between π-‐tail
–Side-‐mount
• Nacelle/Hub/Pylon
–7 addi1onal grids • One for each component
• Two collar grids –Fuselage/pylon, nacelle/pylon
• Two caps for the hub
–nose, base
31
Podded Nacelle
32
Podded Nacelle
• Flow-‐through nacelle
• CL, CD increments w/rt clean configura1on
–Lower CL
–Higher CD
• Compare w/ embedded
• Engine model
33
Outline
• Podded nacelle
34
Conclusions
• CFD predic1ons validate basic ideas behind D8
–Fuselage carries ~15% of the li; at cruise
–Fuselage provides a posi1ve pitching moment at cruise
–Rear of the fuselage acts as diffuser
• CL, CD compare well to the experiment
–Be]er agreement with SST
• Podded: Results in increased drag, reduced li; as expected
35
Future Work
• Placement of Podded Nacelles
• Blended Nacelles
–Original configura1on • Three-‐engine
–Present concept M. Drela, MIT
• Two-‐engine
–Geometry, mesh, CL, CD increments
• CGT
• Blender Sub-‐D surfaces for C-‐2 con1nuity?
• Fan model (pressure disk, rota1ng blades?) 36
Acknowledgements
This work is funded by NASA’s Fundamental Aeronau1cs Program under the Fixed Wing Project
• MIT
–Mark Drela
–Ed Greitzer
–Bob Haimes
–Alejandra Uranga
• NASA Ames
–William Chan
–Ce1n Kiris
–Nateri Madavan
–Mike Olsen
–Thomas Pulliam
–Mike Rogers
37

Cart3D free-air simulation of D8

Transcription

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