How things fly

How things fly!


The amazing science of flight is largely governed by Newton's laws.
Consider a wing cross-section:




Air hits it at a certain speed.  However, the shape of the wing forces air to rush over it and under it at different rates.  The top curve creates a partial vacuum - a region "missing" a bit of air.  So, the pressure (force/area) on top of the wing can become less than the pressure below.  If the numbers are right, and the resulting force below the wing is greater than the weight of the plane, the plane can lift.
This is often expressed as the Bernoulli Principle:
Pressure in a moving stream of fluid (such as air) is less than the pressure of the surrounding fluid.





The image above shows another way to think of flight - imagine the wing first shown, but slightly inclined upward (to exacerbate the effect).  There is a downward deflection of air.  The reaction force from the air below provides lift and the lift is proportional to the force on the wing.
In practice, it works out (in general) to be:
Lift = 0.3 p v^2 A
where p is the density of air, v (squared) is the speed of the plane, and A is the effective area.  Note that the lift is proportional to the speed squared - so, the faster the plane goes, the (much) easier it is to take flight.


Some related animation:




Comments

Post a Comment

Popular posts from this blog

How things wave

Image
How things wave Introduction to WAVES. So - Waves.....   We spoke about energy.  Energy can, as it turns out, travel in waves.  In fact, you can think of a wave as a traveling disturbance, capable of carrying energy with it.  For example, light "waves" can have energy - like solar energy.  Ocean waves can certainly carry energy.   There are several wave characteristics (applicable to most conventional waves) that are useful to know: amplitude  - the "height" of the wave, from equilibrium (or direction axis of travel) to maximum position above or below crest  - peak (or highest point) of a wave trough  - valley (or lowest point) of a wave wavelength (lambda - see picture 2 above)  - the length of a complete wave, measured from crest to crest or trough to trough (or distance between any two points that are in phase - see picture 2 above).  Measured in meters (or any units of length). frequency (f...
Read more

The sound of music

Image
Tonight we will chat about the most well-known of mechanical waves:  sound. Sound is a mechanical wave, meaning that it REQUIRES a medium through which to travel.  Whereas light (or other EM waves) can travel anywhere (more or less), and travel fastest (at the speed of light) through a vacuum, sound is restricted greatly.  It can only travel through a medium, which itself carries the vibrations that are sound waves. The same characteristics previously discussed still apply:  frequency, wavelength, speed, amplitude, crest, trough.  However, sound itself is a longitudinal wave (jiggling "back and forth") rather than a transverse wave (like EM waves, which vibrate "up and down"). Wave definitions to recall Frequency (f) - number of waves per second (measured in hertz, or Hz).  For sound, frequency refers to pitch.  Some frequencies are defined as notes Wavelength ( 𝝺 ) - the length of the wave, from crest to crest, etc. (in m). The...
Read more

Kahoot questions from this evening - answers are below

1.   1.  Which particle is fundamental (unable to be broken up further)? Proton Electron Neutron All are fundamental 2.   2.  When statically charging an object, you are actually moving: Proton Neutron Electron Quark 3.   3.  What is the voltage of a standard D-cell battery? 1 V 2 V 9 V 1.5 V 4.   4.  Two light bulbs are in series. One is unscrewed. What happens to the other one? It also goes It gets brighther Nothing happens It blinks on and off 5.   5.  What is true about the Earth's magnetic North Pole? It is the same as the Earth’s geographic North pole. It is at the equator. It is actually a south pole. None of these are true. 6.   6.  This symbol, a plain rectangle, is the electrical representation of a: Resistor Wire Battery Capacitor 7.   7.  Two light bulbs are in parallel. If the top bulb is unscrewed, what happens to...
Read more