How are Zero G planes able to simulate weightlessness?

In summary: This is typically the case for parabolic paths in most cases.In summary, zero g planes work by simulating a falling elevator effect where the plane drops and the people inside experience weightlessness. The pilot controls the plane's path to maintain this effect, using a parabolic or elliptical trajectory. This allows for brief periods of simulated zero gravity.
  • #1
pr1de
9
0
how do "zero g" planes work?

As the title says, I'm curious about how Zero G planes work. They can't get into orbit , because there's no way they're engines could provide thrust for such speed, and they don't really leave the atmosphere. I've read that they way it's done is by simulating sort of a elevator drop effect, going up... and then dropping , and the persons inside it are floating in free fall. i understand it so far, but when the plane is dropping, and the people are in mid air.. how come the plane's back doesn't smash into them? they would have to be at the exact same velocity ( the human and plane). right?
 
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  • #2


Yes - everything falls at the same speed.
So a plane dropping out of the sky and the people inside it are falling at the same rate and so feel weightless, exactly the same as in a falling elevator.

In practice it's a little trickier, the plane feels the drag of the air around it so wouldn't fall as fast as the people inside - it has to actually power into a particular dive to compensate
 
  • #3


The pilot builds up speed, pulls upwards, then places the plane into a "parabolic" path, which is technically elliptical relative to Earth's' center, adjusting pitch and throttle control to maintain the path. In the NASA version, the plane would pull up into a 45 degree climb, then follow a zero g path until a 30 degree descent, where it needed to pull out to avoid excess speed and loss of altitude. You'd get about 25 seconds of "zero g" every 65 second cycle.

http://en.wikipedia.org/wiki/Vomit_Comet
 
  • #4


Jeff Reid said:
The pilot builds up speed, pulls upwards, then places the plane into a "parabolic" path, which is technically elliptical relative to Earth's' center

If the path is technically elliptical, why is it called parabolic and how can it be described using a parabolic equation? Is it because the path approximates a parabola when there's no great change of distance to the Earth's centre of mass but would be seen to be elliptical if it was possible to follow it through the Earth without impediment?
 
  • #5


thank you for the answers
 
  • #6


Rasalhague said:
If the path is technically elliptical, why is it called parabolic and how can it be described using a parabolic equation? Is it because the path approximates a parabola when there's no great change of distance to the Earth's centre of mass but would be seen to be elliptical if it was possible to follow it through the Earth without impediment?
A parabolic path would occur if the Earth was flat and an infinitely large disk or plane. A relatively low alititudes, and short horizontal distance traveled, the "flat earth" model is close enough. As you mentioned the relative distance traveled relative to the center of Earth would be small. The horizontal distance traveled versus curvature of the Earth would also need to be small.
 

1. How do zero g planes simulate weightlessness?

Zero g planes, also known as parabolic flights, simulate weightlessness by following a parabolic flight path. As the plane ascends, it increases its altitude at a steep angle, creating a period of freefall where the passengers and objects inside the plane experience weightlessness. As the plane reaches the top of the parabola, it begins to descend, and the passengers feel an increase in gravitational force, simulating the experience of gravity on Earth.

2. What is the difference between zero g planes and space flights?

Zero g planes offer short periods of weightlessness, typically around 20-30 seconds per parabola. Space flights, on the other hand, provide sustained periods of weightlessness in orbit around the Earth. Additionally, the altitude reached by zero g planes is much lower than that of space flights, which can reach heights of over 100 kilometers.

3. How are passengers protected during zero g flights?

Passengers on zero g planes are typically required to wear special suits or harnesses to protect them during the periods of weightlessness. These suits provide support and prevent injury from floating around the cabin. Additionally, the interior of the plane is padded and cushioned to minimize any potential impact.

4. How do zero g planes affect the human body?

The experience of weightlessness on zero g planes can have various effects on the human body, including changes in blood pressure, heart rate, and spatial orientation. However, these effects are temporary and generally not harmful to healthy individuals.

5. What types of experiments are conducted on zero g planes?

Zero g planes are used for a wide range of experiments, including studies on the effects of microgravity on plants, animals, and humans. They are also used to test equipment and technology for space missions and to train astronauts for the effects of weightlessness. Additionally, zero g flights are used for educational and entertainment purposes, allowing people to experience weightlessness without going into space.

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