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Trend Analysis

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6000 [ft] hovering altitude. Good autorotation capability. Exceptions ... PSU design group has estimated 60 gallons, for the total required hover time. ... – PowerPoint PPT presentation

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Title: Trend Analysis


1
  • Trend Analysis initial sizing
  • Based on existing helicopters

2
Technion Team
  • Main rotor design
  • Prokopov Oleg
  • Khodos Gregory
  • Schreiber Ilanit
  • Simulations and Trim
  • Perelman Andrey
  • Rind Elad
  • Fuselage design and Weights
  • Kipervaser Galit
  • Adler Gabriela

3
  • Main requirements
  • 2 place training helicopter
  • Turbine engine.
  • Payload of 440 lb 220 kg.
  • Fuel capacity for 2 hours HOGE.
  • 6000 ft hovering altitude.
  • Good autorotation capability.

4
Required Payload 440 lb
Exceptions
5
  • Gross Weight Vs. Payload
  • Fuel capacity for off-trend line designs is about
    15-20 gallons.
  • PSU design group has estimated 60 gallons, for
    the total required hover time.
  • Dragonfly 333 Ultrasport 496 have about the
    same payload but less gross weight.
  • Aerokopterza 6 Air Commander Elite can trade
    payload for fuel capacity.

6
Gross Weight Vs. Payload
  • Both trend lines match the statistics.
  • Therefore the simpler linear trend can be used.
  • Resulting weight-payload function
  • W3.41PL46 lb
  • Gross weight initial estimate 1540 lb.

7
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8
MDL vs. Gross Weight
  • Quadratic estimation slope closer to 1, hence the
    quadratic estimation is the most appropriate for
    light weight helicopters.
  • Weight and MDL calculated by PSU design team
    nearly fits the quadratic trend line.

9
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10
Main rotor diameter vs. Main rotor diameter
estimation.
  • Quadratic fitting based estimation is the most
    suitable for lightweight helicopters.
  • Max Disc Loading function
  • MDL-4.610-8W20.001W1.4 lb/ft2

11
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12
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13
Tip speed Vs. Tip speed estimation
  • We chose the quadratic function is
  • Vtip speed -0.3D225D180
  • Tip speed Estimation using PSUs rotor diameter
    According to the quadratic fitting
  • Vtip speed 640ft/s (about 450 rpm)
  • Data presented here is inaccurate since the
    updated PSU data that we received did not include
    RPM or Tip Speed

14
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15
Empty Weight Vs. Gross Weight
  • We chose the simple linear function
  • EW0.55W19 lb
  • PSUs empty weight 976 lb (443kg) and gross
    weight 1600lb (730kg) nearly fits the trend lines.

16
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17
Useful Weight Vs. Gross Weight
  • We chose the linear function
  • UW0.45W-19 lb
  • Again, the useful weight and gross weight
    calculated by PSU nearly fits the trend lines.

18
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19
Rotor Angular velocity Vs Rotor Dia.
  • We can see that the angular velocity of the Main
    Rotor is of about 470RPM.
  • We chose the linear function
  • Omega-10.8D746 RPM

20
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21
Tail Rotor Diameter Vs. Gross Weight
  • We chose the linear function
  • DTail rotor 0.001W2.45 ft
  • The tail rotor diameter hasnt been decided yet
    by Penn State (2 ft. at least)

22
Schweizer HUGHES 300C
Low Hub
Robinson R22
High Hub
23
Hub
  • Uniform approach to Hub sizing wasnt found
  • Two common trends were tested low and high hub.
  • Main conclusions
  • Hub height will be determined after cabin design.
  • Aerodynamic considerations and FAR will be taken
    into account.
  • Solid body drag can be reduced by using a wing
    shape for the Hub cover.

24
  • Referring to other helicopters, and aerodynamic
    advantage we can make initial estimation of hub
    height 2.42 ft 0.74m.

25
Helicopter Power
  • Parameters - Gross Weight, blade chord, ceiling
    altitude, and main rotor diameter
  • Gross weight - 1540lb (700kg).
  • Chord length - 0.66ft (20cm).
  • Ceiling altitude - 10000ft.
  • Main Rotor Diameter estimated by statistical
    formulae.
  • Those sizes were used everywhere except in
    figures where they were a parameter

26
  • Engine Power was calculated using the relations

27
  • Standard atmospheric model was used.

28
  • Preq increases linearly with Gross Weight at a
    rate of about 7 HP/100lb
  • Power required increases with number of blades

29
  • Ceiling Alt. Preq increases with number of
    blades
  • Preq increases with altitude

30
Boundary Layer separation
  • Chord decreases ? Power decreases
  • Increasing number of blades allows for smaller
    chords
  • Small chords demand higher AOA? boundary layer
    separation
  • Flow separation must be taken into account

31
  • Preq decreases rapidly with rotor diameter
    increase
  • Preq increase at the highest diameters is due to
    induced drag increase at low speeds
  • Increasing the main rotor diameter is desired,
    however, the results should be checked for a
    global optimum.

32
Engine losses
  • Installation losses 5-16 (according to Prouty)
  • Inlet pressure losses due to duct friction
    1-4
  • Inlet pressure losses due to a particle separator
    3-10
  • Exhaust back pressure due to friction
    0.5-2
  • Height losses 1/(0.8_at_6kft)24
  • Wear-out (deterioration) 5-10
  • Engine-mounted accessories 10-15 HP
  • Misc. up to 5

Preq 95 HP gt Peng 145 175 HP Note This
estimation is for continuous power!
33
Preq 95 HP gt Peng 145 175 HP Note This
estimation is for continuous power!
34
Initial Sizing - Summary
  • According to the trend analysis results and the
    demand for 440(lb) 200kg payload
  • Gross Weight 1540 (lb) 700Kg
  • Empty Weight 860 (lb) 400Kg
  • Fuel weight 240 (lb) 109Kg
  • Main Rotor Dia. 26 (ft) 7.9m
  • Maximum DL 2.9 (lb/ft2) 14.2 kg/ m2
  • Angular Velocity 470 RPM
  • Tail Rotor Diam. 3.8 (ft) 1.17m
  • Tail Rotor Arm 15.4 (ft) 4.7m
  • Continuous power 145-175 (HP)
  • In general, approximately Tail Rotor
    Armft(DDtail)/20.5
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