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Title: ead%20aeronautics


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CONCEPTUAL DESIGN OF OPTIMUS A SUPERSONIC
AIRCRAFT FOR SUPERSONIC AIR-LAUNCH AE 440-A
PROF. E. LOTH Nov 28, 2006 300 400pm
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TEAM MEMBERS
  • Nathan Jung Her (Structures)
  • Calvin Lee (Stability and Control)
  • Seiji Matsushita (Propulsion)
  • Phillip Robinson (Costs Con/Ops)
  • Janice Quek (Aerodynamics)
  • Wei Ren Quah (Config., Weights and Balance)
  • Patrick Woo (T.L.) (Performance)

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INTRODUCTION
  • Introduction
  • - Air-launch for more efficient space access
    suggested
  • Request for Proposal (RFP)
  • - Air breathing aircraft to air-launch Falcon 1
    rocket
  • - Launch occurs at altitude of at least 50,000
    ft
  • - 2 lt Mach no. lt 3
  • - Takeoff from a runway in the U.S.
  • - Launch occurs at distance of at least 200
    miles offshore
  • - launch angle ? 25(3 M)

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TEAM THEME
  • Balance between Cost and Performance
  • Performance Payload launch speed
  • - higher launch speed higher delta V gain
  • Design concepts and selection process
  • Specialty areas

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DESIGN CONCEPTS
  • 14 design concepts were compared

  1 2 3 4 5 6 7
Fuselage Flying wing, Swept/Delta Cylindrical Cylindrical Cylindrical Cylindrical blended Cylindrical Flying clamp
Wing Flying wing, Swept/Delta Top, Delta, withCanards Mid, Swept /Delta Low, Delta with Canards Mid, Delta Top, Variable Top to Mid
Tail Twin winglets Conventional Twin winglets Twin verticle tail Twin verticle tail Conventional Conventional
Landing Gear Tricyle Tricycle Tricycle Tricycle Tricycle Mult-bogey Multi-bogey
Engines Turbofan Turbofan Turbojet Turbojet Turbojet Turbofan Turbofan
Payload Captive on Top Captive on Bottom Captive on Top Captive on Top Internal, Captive on Bottom Internal, Captive on Bottom Captive on Bottom
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DESIGN CONCEPTS
  8 9 10 11 12 13 14
Fuselage Cylindrical Blended, Mid, Variable Blended, Mid, Delta Blended, Mid, Delta Flying wing, Delta Cylindrical blended Cylindrical
Wing Top, Swept Blended, Mid, Variable Blended, Mid, Delta Blended, Mid, Delta Flying wing, Delta Low, Swept Low, Swept
Tail Conventional Conventional Twin verticle tail Conventional V-tail Conventional V-tail
Landing Gear Tricycle Multi-bogey Tricycle Multi-bogey Tricycle Tricycle Tricycle
Engines Turbojet Turbojet Turbojet Turbojet Turbojet Turbojet Turbojet
Payload Internal/ Captive on Bottom Captive on Bottom Captive on Top Captive on Bottom Captive on Top Front Captive on Top
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DESIGN CONCEPTS
  • Eliminate designs with the following attributes
  • - Variable wing geometries
  • - Internal/external payload carrying method
  • - Nose forward carrying method
  • Justifications
  • - penalty of weight
  • - complexity
  • - chance of failure
  • - maintenance
  • - stability

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DESIGN CONCEPTS
  • Group remaining design concepts with morphology

  1 2 3 4 5 6 7 8
Fuselage Flying wing, Swept/ Delta Cylindrical Cylindrical Flying clamp Cylindrical Flying wing, Delta Flying Wing, Mid, Delta Cylindrical
Wing Flying wing, Swept/ Delta Top, Delta, With Canards Mid, Swept/ Delta Top to Mid Low, Delta With Canards Flying wing, Delta Flying Wing, Mid, Delta Low, Swept
Tail Twin winglets Conventional Twin winglets Conventional Twin verticle tail V-tail Conventional V-tail
Landing Gear Tricyle Tricycle Tricycle Multi-bogey Tricycle Tricycle Multi-bogey Tricycle
Engines Turbofan Turbofan Turbojet Turbofan Turbojet Turbojet Turbojet Turbojet
Payload Captive on Top Captive on Bottom Captive on Top Captive on Bottom Captive on Top Captive on Top Captive on Bottom Captive on Top
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DESIGN CONCEPTS
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CONCEPT SELECTION
Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria
Criterion Design Concept 1 Design Concept 2 Design Concept 3
Structure 1 3 2
Aerodynamics 1 2 3
GTOW 2 1 3
Stability 2 3 1
Fuel Consumption 2 1 3
Propulsion 1 3 2
Costs 2 1 3
Total 11 14 17
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DESIGN CONCEPTS
3
2
1
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CONFIGURATION, WEIGHTS BALANCE
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CONCEPT SELECTION
Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria
Criterion Design Concept 1 Design Concept 2 Design Concept 3
Structure 1 3 2
Aerodynamics 1 2 3
GTOW 2 1 3
Stability 2 3 1
Fuel Consumption 2 1 3
Propulsion 1 3 2
Costs 2 1 3
Total 11 14 17
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DESIGN CONCEPT 1
Front View
Top View
  • Delta Wings
  • - wing's leading edge remains
  • behind shock wave
  • - high stall angle
  • - simplicity
  • Canards
  • - more statically stable
  • - reduces lift-induced drag
  • Captive on top

Side View
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DESIGN CONCEPT 2
Front View
Top View
  • Delta Wings
  • - wing's leading edge
  • remains behind shock
  • wave
  • - high stall angle
  • - simplicity
  • Flying Wing
  • Captive on top

Side View
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DESIGN CONCEPT 3
Front View
Top View
  • Swept Wings
  • - reduces drag
  • - spanwise flow
  • Captive on top

Side View
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INITIAL SIZING
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Mission Profile
50,000 ft
30,000 ft
30,000 ft
10
0. Start 1. Warm-up and Take-off 2. Climb
3. Cruise out
4. Climb 5. Dash 6. Launch 7.
Descend
8. Cruise in 9. Descend 10. Land
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INITIAL SIZING
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Design Concept 1 Design Concept 1 Mach number Altitude (ft) Range (ft) Wi/(i-1)
0 Start -  0 -  - 
1 Warm-up and Take-off - 0 -  0.9700
2 Climb (to 30,000ft) -  30,000  - 0.9850
3 Cruise out 0.8 30,000 1,056,000 0.9299
4 Climb (to 50,000ft) -  50,000 -  0.9850
5 Dash (for 10 mins) 2.5 50,000 1,640,419 0.9575
6 Payload Drop 2.5 50,000  - 1.0000
7 Descend (to 30,000ft) -  30,000 -  0.9900
8 Cruise in 0.8 30,000 2,696,419 0.8305
9 Descend -  0  - 0.9900
10 Land -  0  - 0.9950
GTOW 314,086 lbs
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INITIAL SIZING
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Design Concept 2 Design Concept 2 Mach number Altitude (ft) Range (ft) Wi/(i-1)
0 Start -  0 -  - 
1 Warm-up and Take-off -  0 -  0.9700
2 Climb (to 30,000ft) -  30,000 -  0.9850
3 Cruise out 0.8 30,000 1,056,000 0.9484
4 Climb (to 50,000ft) -  50,000 - 0.9850
5 Dash (for 10 mins) 2.5 50,000 1,640,419 0.9471
6 Payload Drop 2.5 50,000 -  1.0000
7 Descend (to 30,000ft) -  30,000 -  0.9900
8 Cruise in 0.8 30,000 2,696,419 0.8734
9 Descend -  0 -  0.9900
10 Land -  0 -  0.9950
GTOW 280,576 lbs
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INITIAL SIZING
Design Concept 3 Design Concept 3 Mach number Altitude (ft) Range (ft) Wi/(i-1)
0 Start -  0 -  - 
1 Warm-up and Take-off -  0 -  0.97
2 Climb (to 30,000ft) -  30000 -  0.985
3 Cruise out 0.8 30000 1056000 0.9187
4 Climb (to 50,000ft)  - 50000 - 0.985
5 Dash (for 10 mins) 2.5 50000 1640419 0.9666
6 Payload Drop 2.5 50000 -  1
7 Descend (to 30,000ft) -  30000 -  0.99
8 Cruise in 0.8 30000 2696419 0.8053
9 Descend -  0 -  0.99
10 Land -  0 -  0.995
GTOW 336,306 lbs
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WEIGHT SUMMARY
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Design Concept 1 Design Concept 2 Design Concept 3
GTOW (lbs) 314,086 280,576 336,306
Empty Weight (lbs) 109,526 96,627 118,274
Empty Weight Fraction 0.431 0.438 0.428
Mission Fuel Weight (lbs) 84,113 63,624 97,797
Fuel Weight Fraction 0.331 0.2884 0.3539
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CONFIGURATION OF OPTIMUS
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C.G. of Engines 128.1 ft
C.G. of Fuel 75 ft
Span 95.71 ft
660
Overall C.G. 87.1 ft
C.G. OF Empty Weight of Aircraft
80.75 ft
C.G. of Falcon 1 87.1 ft
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Length of Aircraft 154.79 ft
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AERODYNAMICS
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CONCEPT SELECTION
Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria
Criterion Design Concept 1 Design Concept 2 Design Concept 3
Structure 1 3 2
Aerodynamics 1 2 3
GTOW 2 1 3
Stability 2 3 1
Fuel Consumption 2 1 3
Propulsion 1 3 2
Costs 2 1 3
Total 11 14 17
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NUMERICAL COMPARISONS
Property Design Concept 1 Design Concept 2 Design Concept 3
Property Design Concept 1 Design Concept 2 Design Concept 3
Description Strategic Bomber Flying Wing Conventional Configuration
Maximum Speed Mach 3.1 Mach 0.67 Mach 2.21
Wing Type Delta Delta Aft Swept
Wing Area 6296 5000 6200
Wing Span 105 172 39.9
Sweep Back Angle 66 33 26.6
Aspect Ratio 1.75 5.9168 8
Fuselage Length 185ft 69ft 58.67ft
L/D 8.33 7.03 12.8
CD0 0.013 0.027 0.023
e 0.66 0.7 0.6
CD 0.03 0.03 0.04
CL 0.25 0.211 0.5
Aircraft in Industry XB-70 B-2 Spirit C-5A
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WING GEOMETRY
  • Delta Wing Geometry versus Aft-Swept Wing
    Geometry
  • Performance Characteristics
  • Theme and Team Goals

Balance between COST and PERFORMANCE
Wing Type Delta Delta Aft-Swept
CD 0.03 0.03 0.04
CL 0.25 0.211 0.5
Lift 494485 331437 973892
Drag 59338 47123 77911
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ASPECT RATIO
  • Importance of Aspect Ratio
  • Wing tip Vortices
  • Reducing Induced Drag
  • Reducing Wave Drag

Key Optimizing Aspect Ratio of Wing
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TRADE STUDY EFFECT OF AR ON CD
  • Speeds at Mach 0.8 and Mach 2.5
  • Trend
  • At Mach 0.8, CD decreases as aspect ratio
    increases.
  • At Mach 2.5, CD increases as aspect ratio
    increases

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NUMERICAL ANALYSIS
Using the component build-up method,
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MISSION MODEL
Drag Take-off 59,032lb Subsonic
Cruise 58,800lb Dash
217,695lb After Launch 209,468lb Land
43,246lb
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MISSION MODEL
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FUSELAGE DESIGN
  • At supersonic speeds, one of the greatest
    challenges is to minimize wave drag (pressure
    drag due to formation of shocks)
  • Related to total cross-sectional area of aircraft

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CONCLUSION FUTURE CONSIDERATIONS
  • Preliminary analysis was performed on all 3
    aircraft design concepts.
  • Detailed numerical analysis was conducted of the
    Optimus.
  • FUTURE CONSIDERATIONS
  • Methods to reduce drag.
  • A more refined lift drag model.
  • Airfoil Selection.

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PERFORMANCE
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CONCEPT SELECTION
Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria
Criterion Design Concept 1 Design Concept 2 Design Concept 3
Structure 1 3 2
Aerodynamics 1 2 3
GTOW 2 1 3
Stability 2 3 1
Fuel Consumption 2 1 3
Propulsion 1 3 2
Costs 2 1 3
Total 11 14 17
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FUEL CONSUMPTION
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Mission Profile
50,000 ft
30,000 ft
30,000 ft
10
0. Start 1. Warm-up and Take-off 2. Climb
3. Cruise out
4. Climb 5. Dash 6. Launch 7.
Descend
8. Cruise in 9. Descend 10. Land
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FUEL CONSUMPTION
Design Concept 1 Design Concept 1 Mach number Altitude (ft) Range (ft) Wi/(i-1) Fuel burned (lb)
0 Start -  0 -  -   -
1 Warm-up and Take-off - 0 -  0.97 7,624
2 Climb (to 30000ft) -  30,000  - 0.985 3,697
3 Cruise out 0.8 30,000 1,056,000 0.9299 17,020
4 Climb (to 50000ft) -  50,000 -  0.985 3,387
5 Dash (for 10 mins) 2.5 50,000 1,640,419 0.9575 9,452
6 Payload Drop 2.5 50,000  - 1 0
7 Descend (to 30000ft) -  30,000 -  0.99 2,129
8 Cruise in 0.8 30,000 2,696,419 0.8305 35,732
9 Descend -  0  - 0.99 1,751
10 Land -  0  - 0.995 867
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FUEL CONSUMPTION
Design Concept 2 Design Concept 2 Mach number Altitude (ft) Range (ft) Wi/(i-1) Fuel burned (lb)
0 Start -  0 -  -   -
1 Warm-up and Take-off - 0 -  0.97 7,908
2 Climb (to 30000ft) -  30,000  - 0.985 3,835
3 Cruise out 0.8 30,000 1,056,000 0.9299 17,655
4 Climb (to 50000ft) -  50,000 -  0.985 3,513
5 Dash (for 10 mins) 2.5 50,000 1,640,419 0.9575 9,804
6 Payload Drop 2.5 50,000  - 1 0
7 Descend (to 30000ft) -  30,000 -  0.99 2,209
8 Cruise in 0.8 30,000 2,696,419 0.8305 37,065
9 Descend -  0  - 0.99 1,816
10 Land -  0  - 0.995 899
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FUEL CONSUMPTION
Design Concept 3 Design Concept 3 Mach number Altitude (ft) Range (ft) Wi/(i-1) Fuel burned (lb)
0 Start -  0 -  -  -
1 Warm-up and Take-off - 0 -  0.97 15,498
2 Climb (to 30000ft) -  30,000  - 0.985 7,517
3 Cruise out 0.8 30,000 1,056,000 0.9299 34,601
4 Climb (to 50000ft) -  50,000 -  0.985 6,885
5 Dash (for 10 mins) 2.5 50,000 1,640,419 0.9575 19,214
6 Payload Drop 2.5 50,000  - 1 0
7 Descend (to 30000ft) -  30,000 -  0.99 4,329
8 Cruise in 0.8 30,000 2,696,419 0.8305 72,641
9 Descend -  0  - 0.99 3,559
10 Land -  0  - 0.995 1,762
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FUEL CONSUMPTION SUMMARY
Design Concept 1 Design Concept 2 Design Concept 3
Fuel burned (lbs) 94,264 84,704 166,006
Mission Fuel Weight (lbs) 97,092 87,245 170,986
  • Assuming no payload drop so the Falcon 1 rocket
    can be
  • safely returned
  • Although Design Concept 2 consumes the least
    amount
  • of fuel, Design Concept 1 is chosen

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CONSTRAINT ANALYSIS
  • Take-off with 50ft clearance from 15,000 ft
    runway at sea level
  • Landing distance of 3,000 ft
  • Cruises at M 0.8 at 30,000 ft
  • Dashes at M 2.5 at 50,000 ft

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CONSTRAINT ANALYSIS
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CONCLUSION AND FURTHER ANALYSIS
  • Thrust to Weight ratio of 0.9 is required for
    dash constraint
  • Enough thrust must be provided!
  • Further analysis in the next semester
  • - Maximum dash speed
  • - Maximum altitude

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PROPULSION
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CONCEPT SELECTION
Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria
Criterion Design Concept 1 Design Concept 2 Design Concept 3
Structure 1 3 2
Aerodynamics 1 2 3
GTOW 2 1 3
Stability 2 3 1
Fuel Consumption 2 1 3
Propulsion 1 3 2
Costs 2 1 3
Total 11 14 17
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COMPARISONS
  • Design Concept 1 (BEST)
  • - Able to carry more engines
  • Design Concept 2 (WORST)
  • - Limit of engine size and
  • numbers
  • - Very high thrust engine
  • needed
  • Design Concept 3 (GOOD)
  • - Limit of engine size and
  • numbers

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TURBOJETS
  • Concorde
  • (Rolls-Royce/SNECMA Olympus 593 Mk 602 turbojets
    )
  • XB-70
  • (General Electric J-93 afterburning turbojets

Peter, St. James, The Histroy of Aircraft Gas
Turbine Engine Development in the United States
A Tradition of Excellence 1 st ed., The
International Gas Turbine Institute of ASME.,
1999, pp.430-569
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TURBOFANS
  • F-15
  • (Pratt Whitney F100-220 afterburning turbofans
    )
  • F-111F
  • (Pratt Whitney TF30-111 afterburning turbofans)

Peter, St. James, The Histroy of Aircraft Gas
Turbine Engine Development in the United States
A Tradition of Excellence 1 st ed., The
International Gas Turbine Institute of ASME.,
1999, pp.430-569
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ENGINES DATA
  • Turbojets and Turbofans with Afterburner (AB) at
    Sea Level Condition

Max/Normal Thrust (lb) pc Length (in) Diameter (in) Weight (lb) a
Olympus 593 38,000/32,000 11 280 47.75 7,000 NA
J93 28,000/17,700 13.85 236.3 54.2 5,220 NA
F110-220 23,830/14,670 25 191.2 46.5 3,200 0.6
TF30-P-111 25,100/14,560 21.8 241.7 49 3,999 0.73
Mattingly, D. Jack, Elements of Gas Turbine
Propulsion, 1 st ed., McGraw-Hill, Inc., 1996,
pp.240-265
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SFC vs. Mach
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SFC vs. Mach
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SFC vs. Altitude
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SFC vs. Altitude
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WHICH IS BEST?
  • Turbojets with AB
  • - Higher thrust
  • - SFC is low in dash
  • with AB
  • Turbofan with AB
  • - Lower thrust
  • - SFC is low in cruise
  • without AB

Turbojets with AB are better
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FINAL DECISION
Max/Normal Thrust (lb) SFC (lbm/hr)/lbf SFC (lbm/hr)/lbf
Max/Normal Thrust (lb) Cruise Dash
Olympus 593 38,000/32,000 1.169 1.4
J93 28,000/17,700 0.934 1.45
  • J93 Turbojet with Afterburner is BEST!

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FURTHER ANALYSIS
  • Find more recent engines
  • - Turbojets and Turbofans with AB
  • Design Fuel System and Fuel Tanks
  • General Propulsion System Integration Losses

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STABILITY CONTROL
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CONCEPT SELECTION
Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria
Criterion Design Concept 1 Design Concept 2 Design Concept 3
Structure 1 3 2
Aerodynamics 1 2 3
GTOW 2 1 3
Stability 2 3 1
Fuel Consumption 2 1 3
Propulsion 1 3 2
Costs 2 1 3
Total 11 14 17
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DESIGN CONCEPT 1
  • Cons
  • -Canards are not as common as aft tails
  • -May need high lift airfoil for canard
  • -Difficulty in using flaps
  • Pros
  • -Canards can be made to stall before wing
  • -Enhanced roll rate from elevons

Rank 2nd
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DESIGN CONCEPT 2
  • Cons
  • -Flying wings inherently unstable
  • -Requires complex reflexed trailing edge for
    static stability (inefficient)
  • -May require automatic flight control systems
  • -Complicated wing planforms with varying chords
    and twist to achieve restoring moment

Rank 3rd
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DESIGN CONCEPT 3
  • Cons
  • -V-Tail requires a more complex control system
  • -Significant flight testing needed to program
    V-Tail
  • Pros
  • -Aft tail is a time tested design
  • -Plenty of historical data to compare design
    space

Rank 1st
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INITIAL SIZING
  • Auxiliary Lifting Surfaces
  • - Used historical tail volumes of Large
    cargo/transport
  • aircraft
  • - Fin and canard airfoil is NACA 0012
  • Control Surface Sizing
  • - MILSPEC roll rate for Class III aircraft is 30
    degrees in
  • 1.5 seconds
  • - Initial sizing based on historical data and
    guidelines
  • Final Sizing based on dynamic analysis

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STATIC MARGIN
  • Neutral point calculation completed to determine
    acceptable CG range
  • 5-10 Static Margin for Large Bomber/Cargo
    Aircraft
  • Canard experiences upwash as opposed to tail
    which experiences downwash

Static Margin
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LONGITUDINAL STATIC STABILITY
  • Longitudinal stability most vital to airplane
  • Placing CG ahead of neutral point satisfies one
    of two conditions for stability
  • Must check to see that CM0 is greater than zero
  • Assumed virtually no CG shift from rocket release

Longitudinal Static Stability
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TRIM ANALYSIS
  • Used graphical method rather than iterative
    computational process.
  • Trim analysis shows aircraft can be trimmed for
    many different CL.
  • Subsonic and supersonic trim very similar due to
    comparable CMa .
  • Positive elevon deflection produces upload on
    canard.

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TRIM ANALYSIS
Trim Analysis for Subsonic Cruise
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LATERAL STATIC STABILITY
  • Coupled analysis on roll and yaw
  • Meets the typical yaw moment derivative values as
    described by Raymer.

Lateral-Directional Stability Derivatives
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FURTHER ANALYSIS
  • Must examine dynamic stability and control
    characteristics
  • Investigate high lift airfoils for canard
  • Flexibility Effects
  • Engine out analysis
  • Ground effects
  • Adverse yaw and differential control surface
    inputs

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STRUCTURES
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CONCEPT SELECTION
Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria
Criterion Design Concept 1 Design Concept 2 Design Concept 3
Structure 1 3 2
Aerodynamics 1 2 3
GTOW 2 1 3
Stability 2 3 1
Fuel Consumption 2 1 3
Propulsion 1 3 2
Costs 2 1 3
Total 11 14 17
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STRUCTURAL REQUIREMENT
  • Speed Mach 2.5
  • Altitude 50,000 ft
  • - The speed and the altitude requirements yield
  • - Kinetic heating ranges from -25ºF to 450ºF
  • - Thermal cycling under moisture and radiation
    impact
  • Payload 59,960 lb
  • Must have strong mounts for the payload

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STRUCTURAL SELECTION
  • Selection criteria
  • Feasibility of new concepts
  • Structural strength
  • Minimum Weight
  • Ease of manufacturing

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STRUCTURAL SELECTION
  • Design Concept 1

Pros Cons
Delta wing straight linear structures (spars) enough room for fuel, landing gear, and structure Curved longerons for the fuselage Difficulty placing the rocket
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STRUCTURAL SELECTION
  • Design Concept 2

Pros Cons
Simple geometry for spars and ribs (straight path) Smaller structure (light weight) Weight is distributed along the span of the wing Large cutouts for landing gear (not enough space for both spars and cutout) Extra bulkhead needed for engine mounts
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STRUCTURAL SELECTION
  • Design Concept 3

Pros Cons
Engine inlet structure supports the wing loading Bulkhead in the aft fuselage shares the load with engines and landing gears Excessive structure (fuselage) Wing loading concentrated at the smaller wing root than delta wing
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MATERIALS
Titanium
Stainless Steel Honeycomb
Steel
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BULKHEADS AND LOAD PATH
Rocket Mounts
Forward Bulkhead
Landing Gear Mounts
Engine Mounts
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V-n DIAGRAM
Vdive 3136fps
n7
n
n-3
V (fps)
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CONCLUSION AND FUTURE ANALYSIS
  • Conclusion
  • - Delta wing structure was chosen
  • - No complex composites were used to lower
    the
  • cost
  • Future Analysis
  • - Finite Element Method (FEM) analysis should
    be
  • conducted
  • - Investigate the stress of the rocket
    attachment fittings
  • - Design landing gear

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COSTS
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CONCEPT SELECTION
Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria Concept Selection Criteria
Criterion Design Concept 1 Design Concept 2 Design Concept 3
Structure 1 3 2
Aerodynamics 1 2 3
GTOW 2 1 3
Stability 2 3 1
Fuel Consumption 2 1 3
Propulsion 1 3 2
Costs 2 1 3
Total 11 14 17
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COST ANALYSIS
  • Used RAND DAPCA IV Model
  • - Find approximate unit price
  • Hours needed Engineering, Tooling, Manufacturing
  • Cost estimated Develop, Flight Test,
    Manufacturing, Material, Engineering production

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DESIGN CONCEPT 1
  • We 109,526 lbs
  • Velocity M2.5 at 50,000 ft
  • 1433 Knots
  • Number Produced (Q) 5
  • FTA3
  • Neng40
  • Thrust max 28,000 lbs
  • GE J93 Turbojet w/ AB

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DESIGN CONCEPT 2
  • We 96,627 lbs
  • Velocity M2.5 at 50,000 ft
  • 1433 Knots
  • Number Produced (Q) 5
  • FTA3
  • Neng40
  • Thrust max 28,000 lbs
  • GE J93 Turbojet w/ AB

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DESIGN CONCEPT 3
  • We 118,274 lbs
  • Velocity M2.5 at 50,000 ft
  • 1433 Knots
  • Number Produced (Q) 5
  • FTA3
  • Neng40
  • Thrust max 28,000 lbs
  • GE J93 Turbojet w/ AB

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ESTIMATED COST
Costs Design Concept 1 Design Concept 2 Design Concept 3
Total Cost (5 AC) 8,954,080,073 8,619,522,958 9,851,267,581
Total Cost (Individual) 1,790,816,015 1,723,904,592 1,970,253,516
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DESIGN 1 - OPTIMUS
  • Moderate expensive aircraft to build.
  • Best performance capabilities for the best price
  • Based off a similar design
  • Marketable

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CONCEPT/OPS
  • Base Kennedy Space Center, Cape Canaveral, FL
  • Fly out east of KSC
  • Captive on top delivery
  • ? 25 (3-M)
  • ? 12.5

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CONCLUSION
  • Cost Estimation seems reasonable
  • Moderately expensive out of the three
  • Much cheaper than the traditional launches from
    earth

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CONCLUSION FUTURE PLANS
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CONCLUSION FUTURE PLANS
  • Highly versatile delivery aircraft and favored
    in terms of Structure Stability
  • Optimus meets the RFP
  • Optimus will provide an alternative method to
    deliver rockets into orbit
  • Promote this idea to potential buyers,
    hopefully expanding the market for this
    innovative method to launch rockets into space.
  • Decrease thrust requirement by reducing drag.
    Lower cost. Will be looked into next semester.

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REFERENCES
  • Jenkinson, L., Civil Jet Aircraft Design, AIAA,
    1999
  • Mattingly, D. Jack, Elements of Gas Turbine
    Propulsion, 1 st ed., McGraw-Hill, Inc., 1996,
    pp.240-265.
  • McCormick, B.W., Static Stability and
    Control, Aerodynamics, Aeronautics, and Flight
    Mechanics, 2nd ed, Wiley, New York, 1995, pp.
    473-534.
  • Peter, St. James, The History of Aircraft Gas
    Turbine Engine Development in the United States
    A Tradition of Excellence 1 st ed., The
    International Gas Turbine Institute of ASME.,
    1999, pp.430-569
  • Raymer, D.P., Aircraft Design A Conceptual
    Approach, AIAA Education Series, 2002

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