Effect of the load sequence on the deformation of a spring

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SUMMARY

The discussion focuses on the deformation of a spring under varying load sequences, specifically analyzing the relationship between mass, deflection, and spring rate. When an object of mass 'm' is attached to a spring, the deflection 'd' occurs at equilibrium. Adding another mass 'M' results in a new deflection 'x', with the difference 'x-d' representing the additional deflection. The deflection of a spring is directly proportional to the force applied, governed by the spring rate, measured in N/m or lbs/inch, confirming that the relationship holds regardless of the load sequence.

PREREQUISITES
  • Understanding of Hooke's Law (F = K*x)
  • Knowledge of spring mechanics and deflection principles
  • Familiarity with mass, force, and gravity concepts
  • Basic algebra for calculating force differences
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  • Study the principles of Hooke's Law in detail
  • Explore the effects of dynamic loading on spring behavior
  • Learn about different types of springs and their applications
  • Investigate methods for measuring spring rate accurately
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Mechanical engineers, physics students, and anyone involved in the design or analysis of spring systems will benefit from this discussion.

Nayef
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Consider a spring balance with no initial deflection. Let an object of mass 'm' be attached to it. We allow the spring to come into equlibrium, and 'd' is the deflection at this eqb position. We add another object of mass 'M', while m is also present, so that the final position is x, and hence deflection between the two equilibrium stages is x-d. Now, let 'm' be attached on its own from the zero position of spring and let 'l' be the deflection produced. Will 'l' be less than x-d?
 
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The deflection of a spring is always proportional to the force on the spring, regardless of load sequence. The proportionality constant is the spring rate, normally measured in N/meter or lbs/inch.

At steady state (nothing is moving), the force is due to the mass times gravity. If the mass is dropped onto the spring, an additional force due to the mass times the acceleration is added to the force due to gravity.
 
For the purpose of clarity, does your answer imply that l = x-d?
 
The definition of a spring is Force = Spring Rate X Distance (F = K*x). The distance is the amount of spring compression/tension from its free length. Therefore, if you compress a spring a little bit, you will get a force. Compress it a little farther, and the force will increase. The difference between the two forces is equal to the amount of additional compression times the spring rate. The total force is equal to the the total amount of compression from the free length times the spring rate.

You can calculate two different forces, and subtract. Or you can take the difference between the two compressed lengths and multiply by the spring rate. The force difference will be same either way. You can prove it with some high school algebra.
 

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