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Jul 13, 2023 · A spring has a deflection of 0.2 m when a force of 30 N is applied to it. Determine the constant of elasticity of the spring. Solution : Using Hooke's law formula: F = -kx Where F is the applied force, k is the constant of elasticity and x is the deformation. Rearranging the formula to solve for k: k = -F / x. Substituting the values: k = -30 N ...
Hooke's Law. Hooke's Law. Hooke's Law states that if a spring is not stretched beyond its elastic limit, the force that acts on it is directly proportional to the extension of the spring. Elastic Limit. The elastic limit of a spring is defined as the maximum force that can be applied to a spring such that the spring will be able to be restored ...
Mar 18, 2013 · The equation derived from Hooke’s Law. Spring constant is defined as the ratio of the force applied on a spring to the extension of the spring. It is a measure of the stiffness of a spring or elastic object. Area below the graph = Work done. The higher the gradient, the greater the spring constant and the harder (stiffer) spring.
Hooke’s Law (Hooke 1635-1703) is well-known as the linear relation of stress σ and strain ε with elastic materials: σ=aε (1) But it is also known for a long time, that this linearity is (nearly) right only for smaller values of ε.
Elasticity is the property of an object or material which causes it to be restored to its original shape after distortion. It is said to be more elastic if it restores itself more precisely to its original configuration. A rubber band is easy to stretch, and snaps back to near its original length when released, but it is not as elastic as a ...
Dec 22, 2020 · The equation for Hooke's law is: F=-kx F = −kx. where F is force in newtons (N), x is displacement in meters (m) and k is the spring constant unique to the object in newtons/meter (N/m). The negative sign on the right side of the equation indicates that the displacement of the spring is in the opposite direction from the force the spring applies.
Jun 2, 2024 · Hooke’s Law is the governing principle behind a material’s behavior when subjected to deforming forces. It is applicable within the elastic limits of a material and states that the strain or deformation of a material is directly proportional to the deforming force or stress applied to it.
