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How much fuel is stored in an airplane?
A plane like a Boeing 747 uses approximately 1 gallon of fuel (about 4 liters) every second. Over the course of a 10-hour flight, it might burn 36,000 gallons (150,000 liters). According to Boeing’s Web site, the 747 burns approximately 5 gallons of fuel per mile (12 liters per kilometer).
How much extra fuel do commercial airplanes carry?
Commercial flights typically carry at least one hour’s worth of additional fuel on top of that required to get to their destination, but this is often increased by the pilots depending on the circumstances on the day. Airlines must comply with the regulatory stipulations with regards to carrying fuel.
How much fuel is stored in the wings?
So, in this case the wings together hold approximately 2/3 of the fuel, with 1/3 in the centre tank. If you look at different aircraft the answers can be very different. A Cessna 150 only has wing tanks, so they hold 100\% of the fuel.
Where is the fuel in a plane stored?
wings
Placement. On passenger planes, fuel tanks are often integrated into the wings, and when there are also tanks inside the body of the aircraft, the wing tanks are used preferentially. The placement reduces the stress on the wings during takeoff and flight, by putting the heavy fuel directly inside the source of lift.
How much fuel does an A380 use?
A fuel capacity of nearly 82,000 gallons, a fuel consumption rate of 10 g/nm and space for up to 853 passengers makes the A380 more fuel efficient per passenger than an average economy car.
Why is aircraft fuel stored in wings?
The weight of the fuel provides rigidity to the wing, thereby reducing wing flutter (vibration of the wings due to the airflow). Large flutter is so hazardous that it can even result in total collapse of the wing. Thus, storing fuel in the wings is an exceptionally wise decision which keeps aircraft flying!
Is there fuel in airplane wings?
Fuel is stored in the wings for primarily 3 reasons : Fuel acts as a counter stress for the wings shortly after takeoff when the great stress of the aircraft’s mass acts on them. This prevents a large change in the wing dihedral angle. The weight of the fuel provides rigidity to the wing, thereby reducing wing flutter.