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Objective The Objective is to generate a Chart that relates: RPM

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Presentation on theme: "Objective The Objective is to generate a Chart that relates: RPM"— Presentation transcript:

1 Estimating % Power using Flight Test Data, Thrust HP, and Equivalent Flat Plate Drag

2 Objective The Objective is to generate a Chart that relates: RPM
% Power Output True Airspeed Fuel Flow Range Cruise Altitude

3 Methodology Gather Flight Test Data for a variety of RPM settings (WOT thru economy cruise) For each RPM, record True Airspeed (TAS) at SL, 4000’ and 8000’ density altitude Calculate % Pwr for S.L. data Use the relationship between Density Altitude (DA) and Power Available to estimate % Pwr for 4000’ and 8000’

4 Assumptions Max BHP = 77 HP Prop Efficiency = 75%
I don’t think I’m getting 80 HP based on my maximum RPM of 3300 Prop Efficiency = 75% Equivalent Flat Plate Area (fe) remains constant Changes in TAS are due to changes in engine power (% Pwr) Fuel Flow is proportional to % Pwr

5 130 mph & 58 THP intersect at fe=4 sq ft
RPM = 3300, TAS = 130 mph % Pwr = 100% 130 130 mph & 58 THP intersect at fe=4 sq ft 58 THP = 77 BHP * 0.75 = 58

6 RPM = 3200, TAS = 125 mph 125 50 58 % Pwr = 50/58 = 86%

7 RPM = 3100, TAS = 120 mph 45 58 % Pwr = 45/58 = 77%

8 RPM = 3000, TAS = 115 mph 115 40 58 % Pwr = 40/58 = 70%

9 RPM = 2900, TAS = 110 mph 110 35 58 % Pwr = 35/58 = 60%

10 RPM = 2800, TAS = 105 mph 105 32 58 % Pwr = 32/58 = 55%

11 Findings Equivalent Flat Plate Area (Fe) = 4 sq. ft. RPM TAS % Pwr

12 Findings (cont) Measured WOT Fuel Flow = 5.7 gph
Calculate fuel flow based on % Pwr RPM TAS % Pwr Fuel Flow

13 Effect of Density Altitude on Power Output

14 Findings (cont) Power Output falls with DA
At 4000’ DA, max power output is 87% of S.L. output At 8000’ DA, output is 77% of S.L.

15 Conclusion From here, we can do the math and complete the % Power Table

16

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