The rock on a string demonstrates centripetal force by moving in a circular path due to the tension in the string pulling it towards the center of the circle. This inward force, called centripetal force, keeps the rock moving in a curved path instead of flying off in a straight line.
Some engaging centripetal force activities include swinging a bucket of water in a circle without spilling it, spinning a ball on a string around your hand, or riding a carousel and feeling the outward force pushing you towards the edge. These hands-on activities demonstrate how centripetal force keeps objects moving in a circular path.
A centripetal force apparatus is used to demonstrate the concept of centripetal force, which keeps an object moving in a circular path. It is often used in physics demonstrations to show how an object's inertia tends to keep it moving in a straight line, but centripetal force acts perpendicular to the motion to keep it in a curved path.
The centripetal force in this scenario is manifested as tension in the string. The tension in the string acts as the centripetal force required to keep the stone moving in a circular path. If the tension in the string is too weak, the stone will not be able to maintain its circular motion and will fly off tangentially.
The centripetal force, directed towards the center of the circle, keeps the ball on a string moving in a circle. This force is provided by the tension in the string, which constantly pulls the ball towards the center, preventing it from moving in a straight line. The ball's velocity remains tangential to the circle due to the centripetal force acting perpendicular to the velocity vector, resulting in circular motion.
Four times greater. The force on the string is determined by the centripetal force required to keep the ball moving in a circular path, which is proportional to the square of the velocity. Doubling the velocity will result in four times the centripetal force.
Some engaging centripetal force activities include swinging a bucket of water in a circle without spilling it, spinning a ball on a string around your hand, or riding a carousel and feeling the outward force pushing you towards the edge. These hands-on activities demonstrate how centripetal force keeps objects moving in a circular path.
A centripetal force apparatus is used to demonstrate the concept of centripetal force, which keeps an object moving in a circular path. It is often used in physics demonstrations to show how an object's inertia tends to keep it moving in a straight line, but centripetal force acts perpendicular to the motion to keep it in a curved path.
Centripetal force is the force necessary to apply to an object to get it to orbit; like spinning a rock on a string. It you are holding on to the string, you will feel a centrifugal force.
The centripetal force in this scenario is manifested as tension in the string. The tension in the string acts as the centripetal force required to keep the stone moving in a circular path. If the tension in the string is too weak, the stone will not be able to maintain its circular motion and will fly off tangentially.
The centripetal force, directed towards the center of the circle, keeps the ball on a string moving in a circle. This force is provided by the tension in the string, which constantly pulls the ball towards the center, preventing it from moving in a straight line. The ball's velocity remains tangential to the circle due to the centripetal force acting perpendicular to the velocity vector, resulting in circular motion.
I'm not sure exactly what you are asking, but centripetal force is just a name given to any force that causes circular motion. Swing a rock on the end of a string and the string tension is the centripetal force. Drive a car around a flat circular track and the friction between the tires and the road is the centripetal force. Put a satellite in orbit and gravity is the centripetal force.
The gravitational force acting between the Earth and the Moon is a centripetal force that keeps the Moon in its orbit.
centripetal
Four times greater. The force on the string is determined by the centripetal force required to keep the ball moving in a circular path, which is proportional to the square of the velocity. Doubling the velocity will result in four times the centripetal force.
Swinging a ball on a string around your head demonstrates the concept of centripetal force, where the force is directed towards the center of the circular motion to keep the ball moving in a curved path. This creates tension in the string to prevent the ball from flying off. The speed and distance of the ball depend on the force applied and the length of the string.
A spinning ball on a string being swung around in a circle is a real life example of centripetal force. The force provided by the string towards the center of the circle is the centripetal force that keeps the ball in circular motion.
The tension in the string, which prevents the ball continuing forward in a straight line.