Post on 22-Jan-2016
description
Vertical Takeoff Rescue Amphibious Firefighting Tiltrotor
1
Ryan Berg Alex Carra Michael Creaven Joseph Diner Meagan Hom Ryan Paetzell Jason Smith Alan Steinert James Tenney Bryant Tomlin
2
Purpose: Rescue Missions, and Aerial Firefighting
Vertical Take Off and Landing (VTOL) Amphibious Landing and Take Off Range of 800 nm 50 passengers Cruise of 300 kts
3
4
5
6
Weight Quad-Rotor Dual Fuselage ConventionalPower Required (VTOL) 8 1.82 1.16 1
L/D (Cruise @ 10,000 ft) 7 1.41 1.07 1
Fuel Weight 6 2.1 1.11 1
Disk Loading 5 2.52 1.1 1
Max Bending Moment 4 1.15 1.09 1
CG Movement 3 1 2 2Quantitative TOTAL 57.23 39.29 36
Ease of operation 6 2 3 1
Water stability 12 3 1 3
Rescue Operations 8 3 1 2
System complexity 6 3 1 1
Maintenance 4 3 2 1
Service Life 3 3 1 2
Qualitative TOTAL 111 55 74
OVERALL TOTAL 168.23 94.29 110
7
8
Wing Span = 76.5 ft Wing Area = 625 ft2
Cruise L/D = 12 Gross Takeoff Weight (VTOL) = 62,460 lb Gross Takeoff Weight (short takeoff) = 70,000 lb Fuel Weight = 10,175 lb Max Power Available = 12300 shp Max Speed = 333 kts Rotor Diameter = 42 ft Range = 800 nm
10
11
0 20 40 60 80 100 120 140 160 1800
2000
4000
6000
8000
10000
Alti
tude
(ft)
Time (min)
1
2
4
5
5
6 7
8
10 11
1314
39
12
1 Vertical Takeoff (2100ft/min)2 Transition(30sec)3 Climb4 Cruise5 Glide down6 Conversion7 Landing8 Vertical Takeoff (2100ft/min)9 Transition
10 Climb11 Cruise12 Glide down13 Conversion14 Landing
12
Engine: Rolls- Royce AE 1107C-Liberty Turboshaft
Shp
6150
Dimensions 78.1 by 43.2 inWeight 971 lbs14 stage compressor/2 stage high and 2 stage low pressure turbineSelf- lubricating system for VTOL operation
Maximum Thrust Produced: 77053 lb
Thrust Produced in VTOL: 6950 lb
(Rolls- Royce)
13
14
15
Airfoil r/R
XN25 0.06
XN18 0.12
XN12 0.5
XN08 0.75
XN06 0.99
Rotor airfoil sections and positions as fraction of rotor length
Radius 21 ft
Number of blades 6
Chord 2.97 ft
Twist 39 deg (-48 deg inboard/-30 deg outboard)
Material Fibrous Composite with titanium alloy abrasion strip
Disk Loading 21.98 lb/ft2
Solidity 0.27
Figure of Merit 0.81
Propeller Efficiency 0.78
Coeff. Of Thrust 0.02
Tip Speed Ratio 1.78
(Romander)
• NACA 65(216)-415 a = 0.5 airfoil was selected for all three wings.
• Airfoil Characteristics:• High CL at 0 degrees AOA
• Maintains performance characteristics even at low Reynolds number
• Promotes laminar flow over middle wing
Source: Raymer, Aircraft Design: A Conceptual Approach
Planform Area = 625 ft2
L/D in cruise was calculated over a range of wingspans using a MATLAB drag estimation program
Max obtainable L/D = 12 Corresponding wing span = 76.5 ft
AR = 9.36
17
0 10 20 30 40 50 60 70 80 90 1000
2
4
6
8
10
12
14
16
Wing Span (ft)
Lift
to
Dra
g R
atio
Maximum wing span basedon structural constraints
Design PointL/D = 12
Speed = 300 knotsAltitude = 10000 ft
A drag estimation program provided by Dr. Gur was used to verify the calculated L/D for the aircraft.
A basic VSP representation of the aircraft, as shown on the right, was analyzed at cruise conditions.
An L/D value of 12.5 was calculated by the program.
18
19
0 50 100 150 200 250 300 350 4000
2
4
6
8
10
12
14
16
18
Cruising Speed (knots)
Lift
to
Dra
g R
atio
Altitude = 30000 ft
Altitude = 20000 ft
Altitude = 10000 ft
Altitude = Sea Level
50 100 150 200 250 300 350 4000
2000
4000
6000
8000
10000
12000
14000
16000
Cruising Speed (knots)
Pow
er (
hp)
Power Required
Power Available
Stall Speed
Rotor Tip Speed Limit
Roll rate 3.0o/sec per inch of stick
Yaw rate 3.0o/sec per inch of stick
Pitch rate 4.5o/sec per inch of stick
A total of 6 in of stick Aircraft is Dynamically stable
7%MAC static margin Flaperons 35% chord and are
deflected The rudder is a symmetrical
airfoil (NACA-0012) and the rudder is located at 25% chord
The horizontal tail is at an incidence angle of -1.2o, and the elevator is located at 35% chord
20
Structural design of a rib with the Flaperon
Angle of Attack -8o to 12o
21
-20 -15 -10 -5 0 5 10 15 20-2
-1
0
1
2
3
4
Minimum Cl with Flaperons Deflected
Maximum Cl with Flaperons Deflected
Cl without Flaperons
Upper Control Limit
Lower Control Limit
Cl
-20 -15 -10 -5 0 5 10 15 20-1
-0.8
-0.6
-0.4
-0.2
0
0.2
0.4
0.6
0.8
1
Lower Control Limit
Upper Control Limit
Cm
Nacelles rotate at 3o per second◦ Due to excessive vibrations in transition◦ Pilot Safety
Nacelle limits are 0o to 100o
22
Transition
0 0.2 0.4 0.6 0.8 1 1.2 1.40
500
1000
1500
2000
2500
3000
Alti
tud
e (
ft)
Time (min)
Capable of takeoff in a sea state of up to 4. Sea State 4
◦ Waves of 5 to 8 ft and wind speeds of 17 to 27 kts Determined through static wave analysis
23
Design for Multiple Loading Conditions◦ Aerodynamic Loading◦ Vertical Takeoff/Helicopter Loads◦ Water Loads
Lightest Possible Structure◦ Strut Braced Wing◦ Composite Materials◦ Wing Skin Tapering
Simple Mediation of Aeroelastic Effects◦ Static Wing Tip Deflection Constraints
24
26
0 50 100 150 200 250 300 350 400 450-2
-1
0
1
2
3
4
Velocity, V knots
Load
Fac
tor,
n
Gust Envelope
Maneuver Envelope
Dive SpeedCruise Point
Maximum Load Factor: 3Minimum Load Factor: -1
Cruise Speed: 300 ktsDive Speed: 405 kts
CLmax= 1.5CLmin= -1.0
27
-30 -20 -10 0 10 20 30-6
-4
-2
0
2
4
6
8x 10
4
Wing Location, ftS
hear
, lb
Shear-Aerodynamic Loading
-30 -20 -10 0 10 20 30
0
5
10
15x 10
5 Moment-Aerodynamic Loading
Wing Location, ft
Mom
ent,
ft-lb
-30 -20 -10 0 10 20 30-6
-4
-2
0
2
4
6
8x 10
4 Shear-Vertical Takeoff
Wing Location, ft
She
ar,
lb
-30 -20 -10 0 10 20 30
0
5
10
15x 10
5 Moment-Vertical Takeoff
Wing Location, ft
Mom
ent,
ft-lb
With resulting shear and moment diagrams for traditional wing
28
0 5 10 15 20 25 30 350
0.5
1
1.5
2x 10
6 Vertical Takeoff
0 5 10 15 20 25 30 350
0.5
1
1.5
2x 10
6
29
Vertical Takeoff
30
Traditional Wing Strut Braced Wing (Outboard)
Strut Braced Wing (Inboard)
Strut
Thickness Flange 0.0475 ft 0.019 ft 0.095 ft N/AThickness Web 0.0390 ft 0.018 ft 0.021 ft N/AArea Wing Box 0.4191 ft2 0.1812 ft2 0.7951 ft2 0.1 ft2
Wing Spar Weight 5739 lb 1836 lb 2835 lb 454 lb# of Stringers 4 4 9 N/ARib Spacing 2 ft 2 ft 1.83 ft N/AArea Stringer 0.0035 ft2 0.001 ft2 0.0025 ft2 N/A
Strut Braced wing divided into two sections due to large stresses imparted on the center wing
Weight reduction from strut minimal due to center wing stresses
Total SBW Weight: 5569 lb Weight Reduction: 170 lb
31
Wingbox idealized as rectangle◦ Rear Spar placed at 54.3% chord◦ Front Spar at 16.6% chord
MATLAB routine written to vary size of structural components
Combination of structural components yielding the lightest structure selected
Wing skin thickness tapered linearly from outboard wing root to tip◦ Wing tip skin thickness 0.005 ft
Materials- ◦ PEEK/IM Carbon Fiber (0°, 90°, ±45°)- Spars◦ Cyanate Ester/HM Carbon Fiber (0°, 90°, ±45°)
32
Wing Skin tapering 0.5 ft maximum tip
deflection constraint Moments of inertia
for each configuration checked versus contour plot
Weight Reduction: 327 lb
33
Number of Stringers 6
Rib Spacing 2.0 ft
Area of Stringers 0.01 ft2
Spar Thickness 0.0075 ft
Root Skin Thickness 0.0233 ft
Tip Skin Thickness 0.005 ft
Cross Sectional Area of Wingbox◦ Root 0.3156 ft2
◦ Tip 0.2036 ft2
Weight of Wingbox 2161 lb Maximum Tip Deflection :
◦ 0.44772 ft (5.37 in)
34
Structural Solidworks CAD Model of outboard wing structure created
Finite Element Analysis conducted using ANSYS v.12
FEA results for tip deflection compared to MATLAB results
35
36
Loading ConditionsAerodynamic Loading
◦ All weights assumed to be equally distributed or a point force
◦ Fuselage pinned at the center of lift
Water Landing◦ Fuselage must have a zero
moment around the center of gravity
◦ Buoyancy Force must counteract the moment force around the center of gravity caused by the weight distribution
37
ResultsAerodynamic loading caused much larger moments Aero Load Factor=4.5Water Load Factor=8.34Aerodynamic loading case turned out to be the limiting case
0 10 20 30 40 50 60-1.5
-1
-0.5
0
0.5
1
1.5
2x 10
4
Length (ft)
She
ar F
orce
(lb)
Shear Force Diagram
Aerodynamic Loading
Water Landing
0 10 20 30 40 50 60-10
-8
-6
-4
-2
0x 10
4
Length (ft)
Ben
ding
Mom
ent (
ft-lb
)
Bending Moment Diagram
Water Landing
Aerodynamic Loading
Final Calculated Values
Bulkhead Spacing (ft) 3
Longeron Width (in) 3
Longeron Thickness (in) 0.0629
Skin Thickness (in) 0.05
Can hold 50 passengers and 6 crew
Two side doors Can carry standard 40x48 in
pallet Uses new seats in V-22 from
Golan Industries/Army Division Winches for cargo loading and
rescue
38
1 Multifunctional Displays2 HUD3 Misc. Switches4 Standby Flight Display5 Flight director6 Altimeter and Airspeed7 Throttle Controls8 Control Pedals9 Control Stick
10 Engine Instrument Alert Sys.11 ECS and Landing Gear Controls12 Lights, Icing and Radio Controls
39
SizeSpeed (mph)
Max Load (lb)
Max Pressure (psi)
Max width (in)
Max diam. (in)
Wheel diam. (in)
PLY Rating
Front tire 21 x 7.25-10 210 6400 166 7.2 21.25 10.0 12
Main tire27.75 x 8.75-14.5 225 21500 320 8.75 27.75 14.5 24
Cockpit Utilizes electronic
controls Features HUD
Landing Gear Bicycle design 66.3% TOGW on main
wheels at 35° off CG
Flight Control Sys.◦ Triple redundant FCCs◦ FADEC and AFCS
Electrical Control Sys.◦ Four Honeywell 90 kVA generators◦ Hamilton Sundstrand Power System T-62T-46-2 APU ◦ Single lead acid battery, which provides 24
VDC Hydraulic Control Sys. Environmental Control Sys.
◦ Oxygen-enriched air for crew breathing is provided at 6 stations
◦ GKN Aerospace deicing sys. Fuel System
◦ 1000 gal of fuel in 18 tanks◦ Fuel transfered between tanks to maintain
balance◦ Aerial and ground capabilities
40
Rescue◦ Goodrich 42305 rescue winch 600 lb of lift and
200 ft of useable cable length◦ Can carry 36 litters◦ Aeromedical bay in left fuselage
Firefighting◦ In water or hovering at 10 ft◦ 1500 gal (750 gal in each fuselage)◦ American Turbine AT-309 pumps◦ released through a 20 x 35 in door
41
Water Tank Tests◦ Water Ingestion◦ Sea State Tests
H-V Diagram Wind Tunnel Tests
◦ Aeroelastic Effects◦ Interference Drag
Downwash Verification
42
43
44
45
46
Cost
RDT&E + Flyaway
$ 52,603,400
Operation and Maintenance (per year)
Fuel Cost $ 792,947
Crew Cost $ 770,964
Maintenance Costs
$ 1,277,213
TOTAL $ 2,841,125
Methods described in Raymer
Based mainly off empty weight, maximum speed, the desired production output in five years, number of flight test aircraft, cruise velocity and take off gross weight
49
Addition of a strut can reduce structural weight but also increases aerodynamic drag
Traditional and Strut Braced wings were designed to satisfy the loading conditions specified
Weights for each design compared to judge the benefits
51