Oops, make that 2.5 g's.mgb_phys said:I'm not sure if the design load would include 3.5G.
russ_watters said:Whoa, Jeff, that is veeeeery cool. And amazing that they were so close on their design limit calculations.
Andrew - one thing to remember about such things is that we gain intuitive knowledge of how things work through perceptions in our daily lives. You've driven over enough bridges, looked at enough cranes, seen enough houses being built to get an intuitive feel for how much structure is required to keep them from falling apart. But your perceptions fail you here in two ways:
-Safety factor: For a plane, in the above example 150% - for bridges, I think it is 200% (or even more). So they have more than twice as much support steel as they really need (considering that quite a bit of what a bridge needs to hold up is its own weight). But I bet you'd be terrified if you went over a bridge that had less than half as much steel as you were used to seeing!
-Strength to weight ratio: Bridges, tall buildings, stadiums, etc. are all made of steel (and concrete). Steel is heavy and has a relatively poor strength to weight ratio. Most older airliners are made of aluminum, which has a strength to weight ratio of 2-3x that of steel. Newer planes include some titanium, which has a strength to weight ratio of 3-4x that of steel and carbon fiber, which has a strength to weight ratio 20-40x that of steel.
The F-15 and Mig-25 are remarkably similar in configuration and physical size, but the F-15 is mostly made of aluminum and the Mig-25, being built for the sole purpose of high-speed intercept of the SR-71 and XB-70, was made of nickel and steel to resist the heat of high speed flight. As a result, the empty weight of the Mig-25 is almost twice the empty weight of the F-15 and other performance characteristics (g-load) suffer accordingly. Ironically, the Sovs didn't have the money to buy titanium they themselves dug out of the ground (titanium resists heat even better than steel) - so they sold it to the US (through intermediaries) to build the SR-71!
My favorite.Cyrus said:Did you read the book skunk works?
The wings of an airplane play a critical role in supporting the aircraft's weight, generating lift, and accommodating engines. Let's explore some common questions about how airplane wings function in supporting these forces and engines:
The primary function of airplane wings is to generate lift. Lift is the upward force that opposes gravity and allows an aircraft to become airborne. Wings are designed to create sufficient lift to support the weight of the aircraft and its payload.
Airplane wings generate lift through a phenomenon known as Bernoulli's principle. When air flows over the curved shape of an aircraft wing, it travels faster over the top surface than the bottom surface. This difference in airspeed creates a pressure difference, with lower pressure on the top and higher pressure on the bottom. The pressure difference results in an upward force, which is lift.
Engines on most modern airplanes are not directly attached to the wings but are typically mounted on the fuselage (body) of the aircraft. However, engines do have pylons or mounts that attach them to the wings. These pylons are carefully designed to minimize aerodynamic drag and maintain the aircraft's balance.
Airplane wings support the weight of the aircraft through the lift they generate. When the aircraft is in flight, the wings produce an upward force (lift) equal to the weight of the aircraft. This balance of forces allows the airplane to remain in level flight or climb when engine thrust exceeds drag.
Airplane wings also experience other forces, including drag and thrust. Drag is the aerodynamic resistance encountered by the aircraft as it moves through the air. Thrust is the forward force generated by the aircraft's engines to overcome drag. Wings play a role in minimizing drag by providing lift and shaping the airflow around the aircraft.
Wing designs are tailored to the specific requirements of different aircraft. Factors such as aircraft size, purpose, speed, and payload capacity influence wing design. For example, commercial airliners have large, swept-back wings for efficient cruise flight, while fighter jets have smaller, highly maneuverable wings for agility.
In summary, airplane wings play a crucial role in supporting forces such as lift and accommodating engines. They generate lift through the principle of aerodynamics, allowing the aircraft to counteract its weight. Engines are typically mounted on the fuselage, and wings are carefully designed to minimize aerodynamic drag and meet the specific needs of the aircraft.