Hooke s law gives the force a spring exerts on an object attached to it with the following equation.
Force of spring attached to floor.
A 1 6 kg block on a horizontal surface is attached to a spring with a force constant of 1 0 10 3 n m as in the figure.
When a 333 g mass is placed on.
Then what is the force that keep the mass up from the floor.
What is the.
The block and spring are released from rest and the block slides along the floor.
The spring is compressed a distance.
Uncompressed spring y 0 then the.
The spring is compressed against the floor a child s toy consists of a piece of plastic attached to a spring.
Top of the spring it compresses by 0 12 m.
When the spring is stretched by an distance x its acceleration ddot x is given by m ddot x kx.
The block is at the equilibrium position of the spring.
When the spring is stretched by an amount x there is a tension kx in the spring.
The constant k is the force constant of the spring.
A 2 50 kg block sitting on the floor is attached to a wall by a spring with a spring constant of k 115 n m 1.
In 333 9 m.
The spring has force constant 840 n m.
A block of mass m 1 00 kg is attached to the spring and rests on a frictionless horizontal surface as shown a the block is pulled to a position xi 6 00 cm from equilibrium and released.
A spring is attached to a vertical wall it has a force constant of k 850 n m.
Spring or gravity pulls down and the spring resists the force.
A 2 50 kg block on a horizontal floor is attached to a horizontal spring that is initially compressed 0 0300 m.
When the spring is compressed by x there is a thrust kx in the spring.
The spring is compressed against the floor a distance of 2 00 cm and the toy is.
A spring is attached to a mass and gravity is pulling it down.
The coefficient of kinetic friction between the floor and the block is mu k 0 40.
It is then pulled away from the wall a distance of 78 5 cm consider this the positive direction.
A spring is attached to the floor.