Airspeed Envelop for Air Transport Airplanes Jet transports cruise near mcrit



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tarix27.04.2018
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Airspeed Envelop for Air Transport Airplanes
Jet transports cruise near MCRIT,

  • Pilot must control airspeed within specified limits

  • MCRIT—Mach number where airflow on the airframe first reaches Mach 1 (beginning of transonic flight regime)

  • Force Divergence Mach number—about 5% above MCRIT

    • transonic aerodynamic effects begin

    • nose tuck due to aft movement of Mach wave on the wing

    • high speed stall—boundary layer detaches aft of the Mach wave

  • Must not allow airspeed to reach MCRIT in an air transport aircraft


Definitions

  • VS—1 G stall speed

  • VMO—max operating airspeed to prevent ram-air damage

  • VS and VMO in KEAS are invariant with altitude

  • MMO—max operating Mach number to avoid approaching MCRIT

  • VMMO—airspeed corresponding to MMO

    • decreases as altitude increase in SA because speed of sound decreases while MMO is constant

    • plotted in Figure 3.11, but conventionally labeled MMO

  • MDF—maximum demonstrated Mach number: Mach number at which aircraft has been tested and shown to be controllable

  • MDF > MMO because MMO has a built-in airspeed safety margin


Figure 3.11 Airspeed Envelop for Boeing 767 at 1 G and 300,000# Gross

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Figure 3.13

  • VS(156 KEAS)— minimum airspeed to avoid stalling the wing (typically not VS in performance manuals, which provide a safety margin above the 1 G stall speed) INVARIANT WITH ALTITUDE

  • VMO (390 KEAS) —maximum airspeed to avoid ram air damage (also provides a safety margin) INVARIANT WITH ALTITUDE

  • VMMO (KEAS; labeled MMO)—maximum airspeed to avoid close approach to transonic flight (monitored on the Mach meter) DECREASES AS ALTITUDE INCREASES

  • MMO (not specified in figure) INVARIANT WITH ALTITUDE

  • Crossover altitude (20,000’)—altitude where VMO = VMMO

  • Coffin Corner (60,000’)—altitude where VS = VMMO (near the coffin corner, it is difficult to distinguish a high speed stall from a low speed stall)

  • Allowable Airspeed Range—airspeedMAX - airspeedMIN

    • Below crossover altitude: VMO - VS

    • Above crossover altitude: VMMO - VS

    • At 20,000’, 390 – 156 = 234 KEAS.

    • At 30,000’, 325 – 156 = 169 KEAS.

    • At 40,000’, 260 – 156 = 104 KEAS

Figure 3.12: Airspeed Envelop for Boeing 767 at 2 G and 300,000# Gross

  • G force affects stall speed: 1 G VS = 156 KEAS

  • 2 G V2 = VS G = 156 2  221 KEAS


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Figure 3.12

  • VS = 221 (2 G stall speed)

  • VMO = 390 KEAS,

  • Crossover altitude = 20,000’

    • VMO = airspeed corresponding to MMO = 390 KEAS

    • Below 20,000’, airspeed limited by VMO

    • Above 20,000’, airspeed limited by MMO / VMMO

  • Allowable airspeed range

    • At 20,000’, 390 – 221 = 169 KEAS.

    • At 30,000’, 325– 221= 104 KEAS.

    • At 40,000’, 260 – 221= 39 KEAS

  • Coffin corner = 45,000’

  • Airspeed corresponding to MMO =VS

  • Allowable airspeed range = 221 – 221= 0.



Figure 3.13. Maximum and Minimum B737 Airspeeds by Gross Weight

  • Pilots use a performance table to determine airspeeds operating range

  • 105,000# and FL300: VMAX = 311 KIAS; VMIN = 196 KIAS; Allowable airspeed range = 311- 196 = 115 KIAS

  • 130,000# and FL340: VMAX = 259 KIAS; VMIN = 241 KIAS; Allowable airspeed range = 259- 241 = 18 KIAS

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  • Weight W affect stall speed VS and VMMO but not VMO or MMO [V2 = V1(W2/W1)]

  • Allowable airspeed range gets smaller as

    • weight increases: VS W

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