Equilibrium and Cart Velocity Experiment

What determines the cart velocity when launched by a compressed spring?

When a spring of constant k is compressed by an amount x from its equilibrium length, what factors determine the velocity of the cart when it is launched by the spring?

The Determinants of Cart Velocity launched by a Compressed spring

When determining the velocity of a cart launched by a compressed spring, the key factors involved are the spring constant (k) and the amount the spring has been compressed from its equilibrium length (x). The equation for calculating the cart velocity is v = (kx)1/2. This means that the velocity is dependent on the product of the spring constant and the compression distance, with the square root taken of the result. Therefore, the spring constant and the compression distance are integral in determining the final velocity of the cart.

For example, if the spring constant is 10 N/m and the spring is compressed by 0.2 m, the cart velocity would be (10 * 0.2)1/2, which equals approximately 0.63 m/s. This illustrates how the combination of the spring constant and compression distance influences the velocity outcome.

It's crucial to note that in this scenario, the air track has negligible friction. This means that all the energy initially stored in the compressed spring is completely transferred to the cart, resulting in the cart achieving a specific velocity based on the spring constant and compression distance. Therefore, when all factors are considered, the cart velocity can be predicted accurately using the formula v = (kx)1/2.

Understanding Equilibrium and Cart Velocity Experiment

In this experiment, the relationship between equilibrium, spring compression, and cart velocity is explored. When a spring of constant k is compressed by an amount x from its equilibrium length, the resulting cart velocity upon release depends on the product of the spring constant and the compression distance. This relationship is captured in the equation v = (kx)1/2, where v represents the cart velocity.

By examining how the spring constant and compression distance interact to determine the cart velocity, we gain insight into the principles of energy transfer and mechanical systems. The absence of friction on the air track ensures that the energy stored in the compressed spring is fully utilized to propel the cart, highlighting the efficiency of transferring potential energy into kinetic energy.

Overall, this experiment provides a hands-on demonstration of the physics principles governing equilibrium and mechanical motion. By understanding the interplay between the spring constant, compression distance, and cart velocity, students can grasp the fundamental concepts of energy conservation and mechanical dynamics in a practical context.

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