Figure: Expected Engine Life, from 1C-135(E)C-1, Figure 7-3A.

Eddie Sez:

In the early days of jet engines, turbine blade life was short and engine failures were frequent. Reducing takeoff thrust had a measurable impact on engine life but also put you closer to the end of the runway during takeoff and closer to any obstacles along your initial climb. We used to joke: "Reduced thrust: making do with less of what you didn't have enough to start with."

Gulfstream pilots take note: your reduced thrust is called "Flex Thrust."

One could argue that the benefits of reducing takeoff thrust settings on a modern engine are not as significant as they used to be: engines are more reliable, are designed to operate at higher turbine temperatures, and are computer monitored and controlled. I would argue that modern engines are also much more expensive and if the manufacturer recommends you do it, you should.

What follows comes from the references shown below, with a few comments in blue.

Early Rationale

See Technical / Blade Creep.

[D. P. Davies, Handing the Big Jets.


[14 CFR 25, § 25.101] Performance. General. (c) (c) The performance must correspond to the propulsive thrust available under the particular ambient atmospheric conditions, the particular flight condition, and the relative humidity specified in paragraph (b) of this section. The available propulsive thrust must correspond to engine power or thrust, not exceeding the approved power or thrust less—

(1) Installation losses; and

(2) The power or equivalent thrust absorbed by the accessories and services appropriate to the particular ambient atmospheric conditions and the particular flight condition.

The manufacturer can specify thrust settings as they deem appropriate to achieve the performance dictated by 14 CFR 25.

[14 CFR 25, § 25.143] Controllability and Maneuverability. (h) The maneuvering capabilities in a constant speed coordinated turn at forward center of gravity, as specified in the following table, must be free of stall warning or other characteristics that might interfere with normal maneuvering:

Configuration Speed Bank Angle Thrust/power setting
Takeoff V2 30° Asymmetric WAT-Limited.1
Takeoff V2+XX2 40° All-engines-operating climb.3
En route VFTO 40° Asymmetric WAT-Limited.1
Landing VREF 40° Symmetric for -3° flight path angle.

1 A combination of weight, altitude, and temperature (WAT) such that the thrust or power setting produces the minimum climb gradient specified in §25.121 for the flight condition.

2 Airspeed approved for all-engines-operating initial climb.

3 That thrust or power setting which, in the event of failure of the critical engine and without any crew action to adjust the thrust or power of the remaining engines, would result in the thrust or power specified for the takeoff condition at V2, or any lesser thrust or power setting that is used for all-engines operating initial climb procedures.

While 14 CFR 25 does not forbid increasing power following an engine failure, it does say such a power increase should not be required.

G450 Flex Thrust

Gulfstream does not advocate flex versus rated thrust for the G450 but does offer a few expanded limitations:

[G450 Airplane Flight Manual §Appendix A §1]

  1. FLEX takeoff thrust may be used on dry or wet, hard-surfaced runways, and the takeoff performance computed in this Appendix is limited to takeoffs for nil or uphill runway slopes and no wind or headwind conditions, only. (FLEX thrust cannot be used for takeoffs with tailwind or downhill slope; the AFM or TOLD must be used to properly compute takeoff performance for these conditions.)
  2. FLEX EPR takeoff thrust procedures are prohibited on runways contaminated with standing water, snow, slush, or ice. A contaminated runway is a runway where more than 25 percent of the required field length is covered by standing water or slush more than 0.125 inches (3.2 mm) deep, or that has an accumulation of snow or ice.
  3. Use of Wing Anti-icing bleed is not approved.
  4. The Anti-Skid Brake System must be ON and operating.
  5. The Auto Ground Spoilers must be operative when using 10° flaps for takeoff.
  6. All rated takeoff EPR limitations must be observed.
  7. To ensure that at least 75% of rated takeoff thrust is used and that takeoff configuration warnings are not inhibited, FLEX power settings must not be less than rated EPR levels provided in the FLEX tables.
  8. Both engines must be capable of developing rated takeoff EPR. To check for a deteriorated engine, at least one rated EPR takeoff is required every 100 flights or 100 flight hours, whichever occurs first.
  9. This Appendix does not include any obstacle clearance information. Check obstacle clearance using the charts presented in the Airplane Flight Manual for the selected takeoff flap setting and the assumed temperature. If obstacles are not cleared, decrease the assumed temperature by columns until obstacle clearance has been obtained. New V-speeds and FLEX EPR must then be determined.

Those who don't flex say they don't want to give up the performance, citing the "Runway Behind You" maxim. Me? I flex whenever I can as often as I can. You are giving up a maximum of 25% of the thrust and I always ensure I have at least 2,000 feet of runway to spare. (If not, go into the runway available page of the performance computer and shorten the runway artificially, the performance computer does the rest. What if you lose an engine at V1? The data assumes you will and have a little less thrust makes directional control easier.


14 CFR 25, Title 14: Aeronautics and Space, Airworthiness Standards: Transport Category Airplanes, Federal Aviation Administration, Department of Transportation

Davies, D. P., Handling the Big Jets, Civil Aviation Authority, Kingsway, London, 1985.

Gulfstream G450 Airplane Flight Manual, Revision 35, April 18, 2013

Technical Order 1C-135(E)C-1, EC-135C Flight Manual, USAF Series, 15 February 1966