Item 1513
DESIGN: UniCopter ~
Pusher Prop - Variable Speed Rotors and Prop - Propeller
Notes:
Suppliers of In-flight Variable Pitch Propellers:
Calculations done by Prop Optimizer:
The program PROP OPTIMIZER is in the computer. It appears to be quite sophisticated, however it is a demo program and is limited to 2 blades, Clark-Y airfoil and optimizes only for cruise.
There is an earlier attempt called 'DaveTest' in the 'Prop 20' folder that can be upgraded to suit.
File Name - Full_Uni
Full UniCopter
CONTROL
IOPT= 1 2 3 4 5
PDES= 0
END
DESLIM
ABMIN=
AFLIM= 60.00000000000000 150.0000000000000
CLDES= 0.0000000000000000
DMAX= 60.00000000000000
END
DESVAR
ADRAG= 3.000000000000000
AFDES= 91.56589217959902
ALTCRS= 1000.000000000000
KS= 1.850000000000000
DIAM= 56.93585789454863
OSWALD= 0.8510000000000000
PITCH= 104.3197616468756
RPMCRS= 2523.630235329021
SPAN= 23.00000000000000
VCRS= 187.5000000000000
WTGRSS= 1320.000000000000
END
TABLES
STA= 0.2000000000000000 0.3000000000000000
0.4000000000000000 0.5000000000000000
0.6000000000000000 0.7000000000000000
0.8000000000000000 0.9000000000000000
1.000000000000000
CHORD= 4.485340308311932 4.417419686430269
4.376151460476852 4.318547895083541
4.171529840124497 3.892109560231573
3.507799206040385 2.943800118010361
2.279209729218887
TCTAB= 0.4064000000000000 0.2937000000000000
0.2436000000000000 0.2007000000000000
0.1684000000000000 0.1440000000000000
0.1355000000000000 0.1151000000000000
0.9020000000000000E-01
END
NRUN Number of trial designs run
PAYOFF Objective or merit function. A quantitative measure of
the design goal such as maximum velocity or climb rate.
ADRAG=
3
END
Full UniCopter
@ 08/20/07 17:57:49.22
>>>> OPTIMIZED DESIGN:
VARIABLE INITIALLY OPTIMIZED LOWER LIMIT UPPER LIMIT
AFDES 91.5659 150.000 60.0000 150.000
DIAM 56.9359 60.0000 12.0000 60.0000
PITCH 104.320 66.8980 52.1599 208.640
RPM 2523.63 2700.00 1800.00 2700.00
VCRS 187.500 185.889 140.625 234.375
PROPELLER DESIGN CRUISE PERFORMANCE
NUMBER OF BLADES = 2 VELOCITY, MPH = 185.889
BLADE ACTIVITY FACTOR= 150.000 ALTITUDE, FEET = 1000.00
DIAMETER, INCHES = 60.0000 DENSITY, SLUGS = 0.230921E-02
GEOMETRIC PITCH, IN = 66.8980 THRUST, POUNDS = 305.765
EFFECTIVE PITCH, IN = 72.7033 DRAG, POUNDS = 305.765
ABSOLUTE PITCH, IN = 83.4743 THRUST HP = 151.569
SHAFT HP = 173.823
ALPHA @ 0LL DEG @75%R= 3.34472 HP AVAILABLE = 173.823
DESIGN LIFT COEF, CL = 0.4293 PROPELLER RPM = 2700.00
THRUST COEF, CT = 0.1046 ENGINE RPM = 2700.00
POWER COEF, CP = 0.1454 REDUCT FACTOR = 1.00000
ADVANCE RATIO, J = 1.21172 SFC, LB/HP/HR = 0.520000
MILES/GALLON = 12.3394
EFFICIENCY, ETA = 0.871971 FUEL FLOW, PPH = 90.3881
ETA COMPRESS CORRECT.= 0.00% FUEL FLOW, GPH = 15.0647
ETA PROFILE DRAG CORR= -0.53% SOUND SPEED,FPS= 1112.56
ETA DIAMETER CORRECT.= 0.60% TIP SPEED, FPS = 757.615
ADRAG, SQ FT = 3.00000 TIP MACH NUMBER= 0.680962
CONSTRAINT VALUES MEASURE THE SUCCESS OF THE OPTIMIZATION.
EQUALITY CONSTRAINTS ARE SATISFIED WHEN = 0
INEQUALITY CONSTRAINTS ARE SATISFIED WHEN >= 0
TYPE: EQUALITY = 0, UPPER BOUND = 1, LOWER BOUND = -1
SYSTEM CONSTRAINT VALUES:
NAME TYPE ACTIVE INACTIVE REQUIREMENT
CRUISE SHP=HPA 0 -0.1050E-10 SATISFIED
THRUST=DRAG 0 0.7436E-12 SATISFIED
ALPHA>=ABMIN -1 3345. SATISFIED
PAYOFF= 39.2083 (-VCRS) TRIAL RUNS = 321
GENERAL NOMENCLATURE
AFDES Activity factor per blade. The higher the activity factor,
the more power a blade can absorb (or is required). For a
given diameter, activity factor increases with blade width.
ALPHA Blade angle-of-attack at the 75% radius, degrees. The angle
the incoming air flow makes with the airfoil zero-lift-line.
ANGLE Blade pitch angle at 75% tip radius station measured
with respect to the plane of rotation, degrees.
CL Blade lift coefficient. Design lift coefficient for cruise.
CP Power coefficient: A non dimensional ratio relating power
required to air density, propeller speed squared and
propeller diameter raised to the fifth power. Power
required is proportional to the fifth power of diameter
for other factors being equal.
GENERAL NOMENCLATURE
CT Thrust coefficient: A non dimensional ratio relating thrust
produced to air density, propeller speed squared and
propeller diameter raised to the fourth power. Thrust
produced is proportional to the fourth power of diameter
for other factors being equal.
CS SPEED_POWER coefficient, J/CP^(1/5). A design parameter used
in determining maximum efficiency for cruise propellers.
DIAM Propeller diameter, inches
DRAG Aircraft drag, pounds
ETA Propeller efficiency: ETA=CT*J/CP
A measure of how much power is delivered to the air stream
by the propeller relative to power delivered by the engine.
This value includes compressibility, profile drag and
relative diameter corrections.
GENERAL NOMENCLATURE
ETA COMPRESS CORRECT: A factor indicating the percentage propeller
efficiency is reduced due to sonic compressibility effects
at the blade tip. Zero indicates no compressibility losses.
The optimizer tries to design on balance to minimum loss.
ETA PROFILE DRAG CORR: An efficiency correction due to blade width
or total activity factor and represents the induced losses.
ETA DIAMETER CORRECT: Corrects for the relative influence of body
and engine nacelle size to propeller diameter. Assuming that
the reference point is accounted for in the effective pitch
and ADRAG calibration, this correction is the increase or
decrease in efficiency from the calibrated reference point.
FFGPH Fuel flow in gallons per hour
FFPPH Fuel flow in pounds per hour
HPA Maximum Horsepower Available from the engine at any
given engine rpm.
GENERAL NOMENCLATURE
J Advance ratio J=(V*88)/(RPM*DIAMETER) Where: V=mph,
DIAMETER=ft. In flight the propeller advances a distance
of J times the DIAMETER per revolution.
MPG Aircraft miles per gallon of fuel
NB Number of blades
PITCH Pitch of chord line at the 75% radius station, inches.
The geometric or theoretical advance of the propeller
per revolution.
RHO Atmospheric density, slugs
SFC Specific fuel consumption, lb/hp/hr
SHP Shaft horsepower required at the propeller shaft before
efficiency losses.
THRUST Propeller thrust, pounds
GENERAL NOMENCLATURE
THP Net Thrust Horsepower delivered to the atmosphere by the
propeller after efficiency losses and required for flight,
(THP=SHP*ETA).
TPMACH Tip Mach number
V Aircraft velocity, miles/hour
VS Speed of sound, feet/second
VT Tip speed, feet/second
NRUN Number of trial designs run
PAYOFF Objective or merit function. A quantitative measure of
the design goal such as maximum velocity or climb rate.
PROP OPTIMIZER (tm)
Copyright 1994 Donald R Bates - All Rights Reserved
BATES ENGINEERING, 2742 Swansboro Road, Placerville, CA 95667
Phone/FAX 916-622-1886
Copy Date 12/11/94
Calculations Done by Props17:
JavaProp by Martin Hepperle
:
More Sources for Prop Calculations;
Use the programs PROP20 and [props18.exe], in the computer.
Booklet 'Single Blade Torqueless Helicopter Design', pages 87 to 98, on the bookshelf
The full set of pages of the classic book 'Aircraft Propeller Design' by Weick [1930] is available from the India digital library site. By entering the following into Google [Aircraft Propeller Design. Author1. Fred E Weick. Author2. Subject. Aerodynamics . Language. english. Barcode. 1010010031915.]
For More Information See
:DESIGN: UniCopter ~ Pusher Prop - General - Pusher Prop Assist
DESIGN: UniCopter ~ Pusher Prop - Configuration - Propeller - Single
DESIGN: UniCopter - Pusher Propeller
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Last Revised: November 25, 2008