246.74 or the rounded answer is 247
No. Centripetal force is a real force that pulls objects towards the center of the circular motion. Centrifugal force is a ficticious force that seems to pull an object towards the outside.
That would be the air pushing against the airplane's wings.
Centripetal force is a force that is required to exist to have a circular motion. Thus the centripetal force can be any force that is able to accomplish this task. Examples of centripetal forces are the gravitational force, the electromagnetic force, the frictional force, or the constraint forces. The centripetal force depends on the system that is involved in be in a spin of a rigid body, or of a planetary motion, etc. Each particular system that requires a rotation or a spin needs to have a corresponding centripetal force.
15,625 N
The seatbelts provide centripetal force. Your inertia is focused in a straight line, and the seatbelts pull you into a circular motion against your inertia when you turn. Centrifugal force has absolutely no application in this scenario. It is a fictitious force that only applies to complex free fall problems while the Earth spins below a falling point. It is a 'fudge factor' in the scientific world.
Acceleration in circular motion is the acceleration directed towards the center of the circle, known as centripetal acceleration. It is responsible for keeping an object moving in a circular path rather than in a straight line. The magnitude of centripetal acceleration is given by the formula a = v^2 / r, where v is the velocity of the object and r is the radius of the circle.
That's called 'centripetal acceleration'. It's the result of the centripetal forceacting on the object on the curved path.
The body which is subjected to centripetal acceleration undergoes uniform circular motion.
If an object follows a circular path, it must have a centripetal force on it to keep it moving in a circle. Centripetal means "toward the center of the circle". The force causes Centripetal acceleration toward the center witch is along the radius of the circular path. Tangential acceleration occurs at a Tangent to the circular path and is always perpendicular to the centripetal acceleration. Always perpendicular to the radius of the circle.
a satellite in orbit; it is moving at constant speed but is accelerating outward in circular acceleration, balanced by gravity acceleration (centripetal force).
Calculate the centripetal acceleration, using the formula:acceleration = speed squared / radius Once you have this acceleration, you can use Newton's Second Law to calculate the force.
The centripetal acceleration is v2/r, directed toward the center of the circle..
It's called 'centripetal acceleration', whether or not the speed is constant or the path circular.
It's called 'centripetal acceleration', whether or not the speed is constant or the path circular.
No, If a car moves around a circular race track with any constant speed, the acceleration is directed towards the centre. So it has a centripetal acceleration. The tangential acceleration would be irrelevant unless the car has an instantaneous tangential velocity of zero. Then the centripetal acceleration is zero. However, this would only exist for that small instant in time.
Yes, it is accelerated. Its acceleration is called centripetal acceleration. Its value is given by: a=v2/R
As an object goes round in a circular path, then its velocity will along the tangent at that instant. But centripetal acceleration is normal to that tangent and so along the radius of curvature. As acceleration is perpendicular to the velocity, the direction aspect is ever changing and so the object goes round the circular path.