Yes it does. It has mass and like all other objects it is attracted to other masses. Throwing a parachute out of a plane will demonstrate this. It will head for Earth.
Air resistance acts against the force of gravity, slowing down the descent of a parachute. The larger the surface area of the parachute, the more air resistance it creates, which helps to slow down its fall. Gravity, on the other hand, pulls the parachute downwards with a force proportional to the mass of the parachute. Balancing these forces allows the parachute to descend safely and slowly.
-- The force of gravity is unchanged before and after.-- The force of air resistance on the skydiver is greater before, and less after,because she is falling slower after the parachute opens.-- The effect on her of air resistance is greater after the parachute is open. Theincreased air resistance itself acts on the parachute, and its effect is transferredto the skydiver through her harness.
Gravity pulls the parachute down towards the ground. When the parachute catches air as it falls, it creates air resistance that slows down the descent, allowing the parachute to glide gently to the ground. So gravity doesn't make the parachute go up into the air, but rather helps control its descent.
Gravity is the most valuable force for a parachute. When a parachute is deployed, it creates drag forces that counteract the force of gravity, allowing the parachute and its user to descend safely to the ground.
The main forces acting on a parachute during descent are gravity, air resistance, and the weight of the parachute itself. Gravity pulls the parachute and its load downwards, while air resistance provides an upward force that slows the descent. The weight of the parachute adds to the overall force acting on the system.
Air resistance acts against the force of gravity, slowing down the descent of a parachute. The larger the surface area of the parachute, the more air resistance it creates, which helps to slow down its fall. Gravity, on the other hand, pulls the parachute downwards with a force proportional to the mass of the parachute. Balancing these forces allows the parachute to descend safely and slowly.
-- The force of gravity is unchanged before and after.-- The force of air resistance on the skydiver is greater before, and less after,because she is falling slower after the parachute opens.-- The effect on her of air resistance is greater after the parachute is open. Theincreased air resistance itself acts on the parachute, and its effect is transferredto the skydiver through her harness.
-- The force of gravity is unchanged before and after.-- The force of air resistance on the skydiver is greater before, and less after,because she is falling slower after the parachute opens.-- The effect on her of air resistance is greater after the parachute is open. Theincreased air resistance itself acts on the parachute, and its effect is transferredto the skydiver through her harness.
Gravity pulls the parachute down towards the ground. When the parachute catches air as it falls, it creates air resistance that slows down the descent, allowing the parachute to glide gently to the ground. So gravity doesn't make the parachute go up into the air, but rather helps control its descent.
Gravity is the most valuable force for a parachute. When a parachute is deployed, it creates drag forces that counteract the force of gravity, allowing the parachute and its user to descend safely to the ground.
Because of gravity
A parachute works as the gravity allows the parachute to go up into the air, then the surface area is covered with air resistance.
The main forces acting on a parachute during descent are gravity, air resistance, and the weight of the parachute itself. Gravity pulls the parachute and its load downwards, while air resistance provides an upward force that slows the descent. The weight of the parachute adds to the overall force acting on the system.
Gravity is the force that pulls a parachute and its user towards the ground. When a parachute is deployed, it increases air resistance, which counters the force of gravity and slows down the descent of the user. The balance between gravity and air resistance allows the parachute to lower the user safely to the ground.
In the case of a parachute, the person and parachute fall at a constant speed once the forces acting on them are balanced. This means that the net acceleration, including gravity, is zero. Gravity is still acting on the person and parachute, but it is balanced by the drag force exerted by the parachute, resulting in a constant speed descent.
Yes it would work. But there would be nothing for it to work against, because there is no gravitational force.If there was no gravity and some other force working on the parachute, such us it being pulled behind a car, then if there was air or another fluid present, then there would be drag, just as in a gravity environment.
yes it does cause if there was no gravity then ur parachute would be going up