aerostar fj 100

Transcription

aerostar fj 100

NEXUS
Business Aircraft
Preliminary Design Review
Aerospace Faculty, Technion
17/1/05
Objectives
Development of new generation
Business Aircraft
2
The Team
A N D O S A
B O S A
3
Content
• Market Survey
• Design Point
• Initial Layouts – first phase
–
–
–
–
–
–
External Layout & Aerodynamics
Powerplant
Performance
Internal Layout
Cost
Stability
• Configuration Selection
• Second phase
• Summary
4
Market Survey
5
Market Survey
Price Vs. Passengers
Price Vs. MTOW
35
35
30
30
25
25
20
20
15
15
10
10
5
5
0
0
0
5
10
15
20
0
25
Price Vs. BEW
10000
20000
30000
40000
50000
Price Vs. Range
35
35
30
30
25
25
20
20
15
15
10
10
5
5
0
0
5000
10000
15000
20000
0
0
2000
4000
6000
8000
6
Market Survey
• For the coming years, High demands for small Business
•
aircraft is expected
The sales expectation are 8000 units in the “Business Ultra
Light” category in next 10-15 years.
7
Market Survey
Niche Selection
• There is lack of aircrafts between GE & Bizjet
• Global trend to develop
New Small Business aircraft
• Intervals Definition
– 4 To 10 Passenger
– 1000 To 2000 NM
– 1.5 To 2.5 M$
8
Market Review
Zoom In
Price Vs. MTOW, price under 2.5M$
Price Vs. Passengers, under 2.5M$
2.5
2.5
2
2
7pass.@2MS
1.5
1
1
0.5
0.5
0
0
0
4000kg@$M2
1.5
3
6
0
9
Price Vs. BEW, Price under 2.5M$
1
1
0.5
0.5
0
0
600
1200
1800
2400
Angel 44
D-JET
A-500
Mirage
Leader
Avocet Projet
Aerostar FJ100
Citation 510
4000
1.5
1.5
0
3000
1300NM@$M2
2
2300kg@2M$
2
2000
Price Vs. Range, Price under 2.5M$
2.5
2.5
1000
0
500
1000
1500
2000
Angel 44
D-JET
A-500
Mirage
Leader
Safire Jet
Grob G 160
Avocet Projet
Aerostar FJ100
A-700
Citation 510
9
Market Survey
Aircraft
General
ANGEL 44
D-JETA 500 Mirage Leader Safire Grob
Jet GAvocet
160 NEXUS
Manufacturer
Angel Aircraft
Diamond
Corp.
Adam
Aircraft
AircraftMaverick
Safire Grob
Aircraft
Price
M$
0.7 0.71 0.94 0.97 1.25
1.4 1.64
Accomodation (pilot + pass.) 8
5
6
4
5
6
7
External Dimention:
Wing Span
m
12.16 11.8 13.4 13.1 10.13
12
13
AR
7.06
7.6
Length
m
10.21 10.8 11.2
8.8 8.69 11.1 11.4
Height
m
3.51
3.1 2.9
3.4 2.74 4.57 3.43
Internal Dimention:
Cabin Length
m
3.51
3.5 4.15 3.76 2.64 4.24
5
Max cabin width m
1.07 1.42 1.37 1.26 1.32 1.41 1.58
Max cabin heightm
1.14 1.44 1.31 1.19 1.09 1.37 1.42
Weights
Basic Empty Weight
kg
1760 1175 1905 1409 1315
Max Takeoff weight
kg
2631 1999 2858 1969 2630
3300
Max payload
kg
559
635
720
Performance:
Range
NM
1720 1320 1470 1345 1500 940 1782
Cruise Speed Knots
175 315 230
394
350 380
270
Max Mach
0.297 0.53 0.39 0.67 0.594 0.64 0.46
2
6
2
7
12.29
13
11.28
3.94
11
4.47
1.48
1.45
4
1.7
1.55
1987
3247
635
875
1200
365
0.619
1300
360
0.6
10
Design Point Definition
• Price:
• Passenger:
• Range:
• Cruise:
2 M$
1Pilot+1+6
1300 NM
0.6 Mach @ 30Kft
11
Range Capability
1300 NM
12
Initial Layout – First Phase
The Vision
Biscuit
TurboFan
TurboProp
13
The Vision
• The group divided into 2 Work Groups
TurboFan Team
TurboProp Team
14
Turbofan
15
Initial Layout – Turbofan
External Layout - initial Sizing
• Takeoff Weight
– Assumption:
• Payload – 715 kg ( =1pilot x 85pass + 7x(85+20) )
• Max L/D = 15
(for cruise 0.866 x 15 = 12.9)
• Profile (Acc. To FAA)
Cruise to Dest
Cruise to Alt
Loiter
LND
Takeoff
16
• Wo = Wf + Wu + We
• Fuel friction –
Wf
 0.241
Wo
Wu
W

o
We
Wf
1

Wo
Wo
Wu
Wu


1 0.58 0.253
0.179
(Inc. fuel for: s\u, Tx, TO, climb, cruise, endurance, decent, alternate)
• Fuel friction Aerospace Faculty, Technion
We
 0.58
Wo
Wu
715
W 

~ 4000[kg]
o 0.179 0.179
17
• Wing Loading
(T@SL/MTOW)
– Affect all flight performance
– W/Sref Design To Parameter
(cruise, endurance, TO/Lnd, Mach,…)
Condition
TO & Land
Cruise
Endurance
Competitors
W/S [kg/m^2] Wing Area
250
16
[m^2]
240
16.7 [m^2]
415
220-300
9.6
[m^2]
13-18[m^2]
kg
m2
W/S ~ 250
2
Sref = 16.5 m
18
External Layout – Wing
C
Defining AR : AR  a  M Max
when a  7.5 c  0  AR  7.5
 AR  7.5
W
  250
S
 b  11 m, chosen due to wing load


b2
= 16.12 m 2
 calculating the wing area : Sreff =
AR

Sweep Angle  M max  0.6  sweep  6.5
Taper ratio, recommended


Ctip
Croot
 0.4
Dihadral 4
19
External Layout – Tail
Horizontal tail
C  1.553 m, CHT  0.8, LHT  5.5
S HT 
Vertical tail
CVT  0.07 , LVT  5.5
SVT 
CHT C W SW
 3.46 m 2
LHT
  0.4, Croot _ HT  1.33 m, sweep  12
CVT bW SW
 2.14 m 2
LVT
AR  0.95
b VT  AR  SVT  1.43 m
sweep 40 ,   0.8
20
External Layout – Airfoil
1 W 
 
q  S Cruise
start : W  4000kg  CL _ start  0.315
CL 
end : W  3200kg  CL _ end  0.252
CLdesign 
CL, cruise _ start + CL, cruise _ end
2
The considerations that were taken:
 0.284
L
 The airfoil that gave us minimal drag for the chosen C L design -  
 D  min
 Sufficient volume for fuel
 The ranges of C L values during the cruise is within the "Drag bucket".
21
External Layout – Airfoil
The chosen Airfoil is :
NACA series 6 :
642 215
Max thickness : 0.4 Chord
Design lift coeff : 0.2  0.2
Max thickness : 15%
22
External Layout – Fuselage
• Circular cross section
– By eliminating corners, the flow will not separate at
moderate angles of attack or sideslip i.e low drag
– Productivity
– Low Cost
– When the fuselage is pressurized,
a circular fuselage can resist the loads
with tension stresses, rather than the more
severe bending loads that arise on non-circular
shapes.
23
Body Profile Comparison
SINO SWEARINGER SJ30-2
AEROSTAR FJ-100
DIAMOND D JET
HP ALEKTO TT62
MAVERICK LEADER
PIPER MIRAGE
ADAM A700
ADAM A500
GROB G 160
CL
1.45 m
AVOCET PROJECT
ECLIPSE 500
BEECH 390 PREMIER 1
CESNA 510 CITATION MUSTANG
24
Engine Selection
• Thrust To Weight ratio
(T@SL/MTOW)
– Affect all flight performance
– T/W Design To Parameter
(cruise, endurance, TO/Lnd, Mach,…)
condition
Mach
Cruise
T/W
0.23
0.31
Thrust
9
[kN]
11.8
[kN]
TO & LND
0.34
13.3
[kN]
T/W = 0.33
Competitors 0.33 -0.4 12.9-15.7 [kN]
25
Engine Selection
• Total Thrust 13.3 [kN]
(or 6.65 [kN] per engine)
• Optional engines:
Williams FJ44-1C
Williams FJ33
AGILIS TF1200
26
Engine Selection
• Williams International FJ-33 was selected
for the following reasons:
– Total Thrust 13.5 [kN]
– Low weight
– Small dimensions
– High T/W ratio
– Low costs
– Proved itself on other aircrafts
27
Internal Layout
• Ergonomic design:
– Passenger sits in a
comfortable position
– Sufficient room for
passenger’s legs
180 cm
170 cm
145 cm
40 cm
– Window located at face
height
– Comfortable 40 cm wide isle
28
Internal Layout
• Seat design:
– 40X40 cm² seat basis
– 66 cm long seat back
– Seat back diverted
backwards by 25°
– Comfortable hand and
head rests
66 cm
65°
40 cm
40 cm
29
Internal Layout
• Cabin design:
– Cylindrical cabin 4m long
– 4 passengers sits in dual clubs plus two forward
heading seats
– 1 passenger sits with the pilot at the cockpit
FORWRAD
4m
30
Internal Layout
• Aircraft cutaways
31
Performance
Subject Condition Parameter
Unit
S.R
[NM/kg]
S.E
[Sec/kg]
Fuel
Cruise
Fuel Req. for Mission
[kg]
Fuel Vol. for Mission
[liter]
V for Best ROC
[knot]
Max ROC
[ft/min]
Climb
S.L
V for Best Angle
[knot]
Best Angle - Two Eng. [deg]
Best Angle - One Eng. [deg]
Glide Slope
[deg]
TO Dist
[m]
Runway
S.L
BFL
[m]
LND Dist
[m]
Value
1.71
24
875
1122
293
6390
152
16.0
6.1
-5
508
1821
638
32
Stability
2 cases were analysis:
Forward CG
Backward CG
Max Passenger
No Passenger
No fuel
Max fuel
33
Stability
Backward CG
9% Stability
Margin
34
Stability
Backward CG
9% Stability
Margin
35
Stability
Forward CG
18% Stability
Margin
36
Stability
Forward CG
18% Stability
Margin
37
Initial Layout – TurboFan
Price
• A price estimation for a turbofan business-jet
with two engines is about 2.5M$.
• This price estimation is also based on delivery of
600-700 planes
38
Turboprop
39
Initial Layout – Turboprop
3600 kg
W/S ~ 210
kg
m2
Sref = 17 m^2
40
12.6 m
External Layout
10.8 m
f1.8 m
41
AR  9.2
External Layout
S  17 m
Croot  1.64 m
2
Ctip  1.08 m
  0.66
 L.E .  10
T . E .  5
42
External Layout
Selected airfoil
NACA series 6 :
641212
Max thickness : 0.4 Chord
Design lift coeff : 0.2  0.1
Max thickness : 12%
43
External Layout
Selected airfoil
44
Engine Selection
• T/W=0.23
T.O thrust 8.5KN
• Turboprop engines survey led to PT6A-41
• Full feathered HARTZELL propeller
• Constant Speed Unit
45
Engine parameters:
• Power: 534kW
• takeoff SFC:
•
0.65lb/h/hp
Weight: 183kg
MATLAB SIMULATION:
Takeoff thrust: 9400Nt
Cruise Thrust: 3100Nt
46
Performance
Subject
Condition Parameter
Unit Value
S.R
[NM/kg] 1.73
S.E
[Sec/kg]
18
Fuel
Cruise
[kg] 2060
[liter] 970
V for Best ROC
[knot] 204
S.L
Max ROC
[ft/min] 1780
V for Best ROC
[knot] 330
Cruise
Max ROC
[ft/min] 403
V for Best Angle
[knot] 115
Climb
S.L
Best Angle - Two Eng.
[deg] 10.70
Best Angle - One Eng.
[deg] 3.63
V for Best Angle
[knot] 225
Cruise
Best Angle - Two Eng.
[deg] 3.10
Best Angle - One Eng.
[deg] -0.03
Glide Slope
[deg] -5.36
TO Dist
[m] 580
Runway
S.L
BFL
[m] 1638
LND Dist
[m] 494
47
Internal Layout
f1.8 m
4.5 m
48
Stability
(Backward CG)
12
11
10
9
8
7
6
5
5.5% Stability
Margin
4
3
2
1
0
1
0.8
‫כנף‬
0.6
‫נ וסע ים‬
‫דלק‬
0.4
‫ א ו ו י ונ יקה‬+‫ט י יס‬
0.2
‫מנ וע ים‬
0
‫קנרד‬
-0.2
‫ג וף‬
Xcg2
-0.4
Xn
top
-0.6
zero
Wa.c
-0.8
-1
canard_start
49
Stability
(Forward CG)
~35% Stability
Margin
50
Initial Layout – TurboProp
Price
• The estimated price at delivery of a business
•
aircraft with two Turboprop engines is 2.58M$
(in 2004 Consumer Price Index USD)
This price estimation based on delivery of
300-400 planes
51
Configuration Selection
52
Comparison Table
Turboprop
+
Turbofan
-
Performance
-/+
+
Appearance
+
+
Challenging Concept
+
-
Development Risk
-
+
Cost (TOC,LCC)
+
-
Innovation
53
• Commercial project Attitude
• Student project Attitude
54
And The Winner is:
55
Second Phase Layout
56
Second Phase Layout
External Layout
57
Second Phase Layout
External Layout
58
Second Phase Layout
External Layout
13 m
11 m
1.8 m
13 m
59
Second Phase Layout
Internal layout
1.6 m
0.45 m
4m
60
Second Phase Layout
Cockpit
61
Second Phase Layout
Engine selection
New engine was selected: P&W Canada PT6A-66
-Better performance
-High reliability with business turboprops
like the Piagio P.180 Avanty.
-Reverse configuration is available
62
Second Phase Layout
Performance
AR
9.2
9.2
8
Old
S
18.4
15.9
15.9
Eng
Value
1.75
50
798
1023
105
2257
170
682
120
13.38
4.99
245
3.98
0.38
5.36481
1098
494
Value
1.75
42
790
1013
110
2336
180
679
120
13.10
4.71
245
3.85
0.26
5.41530
1158
Value
1.75
42
808
1035
115
2427
185
643
120
12.84
4.46
245
3.69
0.10
5.91531
1534
Value
1.75
50
798
1023
105
1780
170
403
115
10.70
3.63
225
3.10
0.035.36580
1638
541
525
494
Subject Cond. Parameter
Unit
S.R
]NM/kg[
S.E
]Sec/kg[
Cruise
]kg[
Fuel
]liter[
V for Best ROC
]knot[
S.L
Max ROC
]ft/min[
V for Best ROC
]knot[
Cruise
Max ROC
]ft/min[
V for Best Angle
]knot[
S.L .Eng Two - Best Angle
]deg[
.Eng One - Best Angle
]deg[
V for Best Angle
]knot[
Cruise .Eng Two - Best Angle
]deg[
Climb
.Eng One - Best Angle
]deg[
Glide Slope
]deg[
TO Dist
]m[
S.L
BFL
]m[
LND Dist
]m[
Runway
63
Second Phase Layout
Performance – flight envelope
Ceiling ~ 40kft
64
Second Phase Layout
Stability
A MATLAB program was used to decide the
final NEXUS configuration ,checking a wide veriaty
of wing(includes fuel & engines) - canard locations,
for static margin of about 7 percent .
Based mainly on the pilots field of view and the
Landing gear location this configuration was chosen.
Xn = 6.4258 m
Xcg1 = 6.3234 m
Xcg2 = 5.7710 m
Wing T.E = 10 m
Canard L.E = 0.5 m
65
Second Phase Layout
Stability
12
11
10
9
8
7
6
5
7%-35% Stability
Margin
4
3
2
1
0
1
0.8
‫כנף‬
‫נ וסע ים‬
0.6
‫דלק‬
0.4
‫א ו ו י ונ יקה‬+‫ט י יס‬
0.2
‫מנ וע ים‬
0
‫קנרד‬
-0.2
‫ג וף‬
Xcg1
-0.4
Xn
top
-0.6
zero
Xcg2
-0.8
-1
canard_start
66
Second Phase Layout
Landing Gear
• Constraints on Landing Gear
– Static Stability on Ground
• Cg behind midpoint of WheelBase
– Dynamic Stability on Ground
• Overturn angle – lower than 63 deg
• Vertical Angle = max(Tipback,Rotation)
– Weight on Nose Wheel
• 8%< W <15%
– Smooth ride
• Strut travel angle ~ 7 deg
67
Second Phase Layout
Landing Gear
1.4  m
1.6 ]m[
15
68
Second Phase Layout
Landing Gear
1.4  m
7
40
20
13
69
Summary
70
Summary
Configuration evolution
71
Summary
Next Semester Goals
• Conceptual Design of Aircraft’s systems
–
–
–
–
Avionics
Electricity
Fuel
Maintenance Hatch
• Detailed Design of chosen Elements:
– Wing
• Structure
• Aerodynamics Surfaces
• Wing Assembly (Engines, Body)
72
Summary
Next Semester Goals
• Detailed Design of chosen Elements:
– Landing Gear
– Internal Layout
• Wind tunnel Test !!!
– Strake configuration
– Vertical stabilizers
73
Doing Business with Class

aerostar fj 100

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