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Flight Simulation

Flight simulation (FSX): a C-17A at the Block Island airport (KBID) in USA

Alex Geoff, the ORBX Block Island (KBID) virtual airport designer, asked flight simulator enthousiasts to try to operate the biggest aircraft possible on that airport ‘s 2502 ft runway.

Canadian military aircraft C17-A ready for take-off runway 10 at the Block Island (KBID) virtual airport in United States (FSX)
Canadian military aircraft C17-A ready for take-off runway 10 at the Block Island (KBID) virtual airport in United States (FSX)

Naturally, we are talking about a virtual flight. You must then forgive the landing of an aircraft which, in real life, would destroy the runway. You also have to disregard the fact that numerous trees would have to be chopped if the aircraft would elect to use the taxiway. I was almost forgetting the pilots and airport manager that would have to be fired following the authorized manoeuver.

The context of the flight having been presented, here is the data that will allow flight simulator enthousiasts to replicate the circuit around the Block Island airport with a Virtavia C-17A.

Contrary to the Cessna type aircrafts normally evolving around the airport, the total weight of the canadian military C-17A used for the flight was 405,000 pounds. The fuel was adjusted to 50% in all four tanks. Both pilots agreed to skip lunch in order to avoid adding any extra weight to the beast…

Flaps were adjusted to 2/3. I backed the aircraft to the beginning of the runway, applied the brakes, applied full throttle, waited for maximum regime, released the brakes and used ground effect to lift the aircraft before it was too late. The take-off was done on runway 10 with a 12 kts and 70 degree crosswind.

Canadian military aircraft C17-A airborne runway 10 at the Block Island (KBID) virtual airport in United States (FSX)
Canadian military aircraft C17-A airborne runway 10 at the Block Island (KBID) virtual airport in United States (FSX)

Then, four right turns were made : 190°, 280°, 010° and 100°. During the flight, the aircraft’s altitude never went above 2000 feet.

Canadian military aircraft C17-A turning downwind runway 10 at the Block Island (KBID) virtual airport in United States (FSX)
Canadian military aircraft C17-A turning downwind runway 10 at the Block Island (KBID) virtual airport in United States (FSX)

Wheels and flaps were brought down in base so that I did not have to make serious adjustments on final.

Canadian military aircraft C17-A turning base runway 10 at the Block Island (KBID) virtual airport in United States (FSX)
Canadian military aircraft C17-A turning base runway 10 at the Block Island (KBID) virtual airport in United States (FSX)
Canadian military aircraft C17-A on long final runway 10 at the Block Island (KBID) virtual airport in United States (FSX)
Canadian military aircraft C17-A on long final runway 10 at the Block Island (KBID) virtual airport in United States (FSX)
Canadian military aircraft C17-A short final runway 10 at the Block Island (KBID) virtual airport in United States (FSX)
Canadian military aircraft C17-A short final runway 10 at the Block Island (KBID) virtual airport in United States (FSX)

The speed eventually went down to 128 kts and, while the aircraft was still about two feet in the air, I used the airbrakes. The thrust reversers were fully activated two feet before touch-down (continued pressure on F2) since they take time to rev up. That is not necessarily the proper way to do it and you can wait one more second, until the wheels touch the runway, to use the reversers. The main gear touched at the very beginning of the runway and maximum breaking was then applied.

Canadian military aircraft C17-A landing at the Block Island (KBID) virtual airport in United States (FSX)
Canadian military aircraft C17-A landing at the Block Island (KBID) virtual airport in United States (FSX)

It was possible to exit on the taxiway without having to back-track on the runway. The environment always coming second, some trees were cut so that there were no contacts with the aircraft.

Canadian military aircraft C17-A exiting runway 10 at the Block Island (KBID) virtual airport (FSX) in United States
Canadian military aircraft C17-A exiting runway 10 at the Block Island (KBID) virtual airport (FSX) in United States
Canadian military aircraft C17-A taxiing at the Block Island (KBID) virtual airport (FSX) in United States
Canadian military aircraft C17-A taxiing at the Block Island (KBID) virtual airport (FSX) in United States

If you decide to try it out, think of saving the flight when you are on final, in case you are not satisfied with your performance during the landing (scrapped aircraft, destroyed houses and vehicles in the neighborhood, burned forest at the end of runway 10, collateral victims, etc.).

Canadian military aircraft C17-A at the Block Island (KBID) virtual airport (FSX) in United States
Canadian military aircraft C17-A at the Block Island (KBID) virtual airport (FSX) in United States

Good luck!

For other challenging virtual flights, head towards the flight simulation section of the present web site.

For more articles on flight simulation on my web site, click on the following link : Flight simulation

Categories
Flight Simulation

Flight Simulation: a B-52 from Montreal to Anchorage, Alaska

Boeing B-52 (FSX) airborne from Montréal Pierre-Elliott-Trudeau Intl to Anchorage, Alaska
Boeing B-52 (FSX) airborne from Montréal Pierre-Elliott-Trudeau Intl to Anchorage, Alaska
Boeing B-52 (FSX) building up speed between Montréal and Anchorage
Boeing B-52 (FSX) building up speed between Montréal and Anchorage

The Boeing B-52 is a Captain Sim creation and the Montreal airport is made by FlyTampa. The remaining scenery is designed by ORBX. Here are few basic informations for those of you who would be tempted to try a flight immediately after the download is completed. For the takeoff: pitot heat, 100% flaps down, YAW SAS Switch Engage, stabilizer trimmed, full throttle within four seconds, climb between 1500 and 2000 ft/min. The climb with flaps down is done at 180 kts. Adjust the thrust so that you have time to bring the flaps in totally; use 230 kts as maximum for zero degree flaps. Once in flight, brake to stop the wheels rotation then bring the gear up (although not before reaching 1000 ft agl).

B-52 at cruising altitude (FSX)
B-52 at cruising altitude (FSX)
Boeing B-52 inbound to Anchorage, Alaska (FSX)
Boeing B-52 inbound to Anchorage, Alaska (FSX)

For a normal descent: (note: keep 20 kts in surplus of the proposed speed when the aircraft is turning). The descent is done at about 240 kts, with airbrakes 4, gear down, throttle to idle. À 220 kts, you may start applying flaps (they take 60 secondes to be fully extended). Once in downwind, use153 kts with airbrakes 4 (for 225,000 lbs). No more than 30 degrees turns. The rollout is done at no more than133 kts.

Boeing B-52 with flaps and gear out on the approach for Anchorage (FSX)
Boeing B-52 with flaps and gear out on the approach for Anchorage (FSX)
Boeing B-52 with runway in sight in Anchorage (FSX)
Boeing B-52 with runway in sight in Anchorage (FSX)
Boeing B-52 and the parachute on the arrival at Anchorage (FSX)
Boeing B-52 and the parachute on the arrival at Anchorage (FSX)

The touchdown with airbrakes full up is done at 110 kts IAS. The drag chute is then deployed (never above 135 kts). Keep a slight angle only, with the rear wheels touching first. When taxiing, turn the YAW switch and the airbrakes to “OFF”. Those are only basic infos. By the way, when the drag chute is deployed, you will not see a difference in the breaking distance; the chute is there only for “graphic” reality.  Have a good flight!

Boeing B-52 leaving the runway in Anchorage (FSX)
Boeing B-52 leaving the runway in Anchorage (FSX)

For more articles on flight simulation on my web site, click on the following link : Flight simulation