Modeling a falling slinky

TL;DR

This paper develops a modified model for a falling slinky that includes finite collapse time, successfully fitting observed data and aligning with measured oscillation properties.

Contribution

It introduces a finite-collapse time modification to an existing tension spring model, improving the understanding of slinky dynamics during free fall.

Findings

The model accurately fits the observed collapse behavior of real slinkies.

The spring constant values from the model are consistent with oscillation measurements.

Finite collapse time is crucial for realistic modeling of a falling slinky.

Abstract

A slinky is an example of a tension spring: in an unstretched state a slinky is collapsed, with turns touching, and a finite tension is required to separate the turns from this state. If a slinky is suspended from its top and stretched under gravity and then released, the bottom of the slinky does not begin to fall until the top section of the slinky, which collapses turn by turn from the top, collides with the bottom. The total collapse time t_c (typically ~0.3 s for real slinkies) corresponds to the time required for a wave front to propagate down the slinky to communicate the release of the top end. We present a modification to an existing model for a falling tension spring (Calkin 1993) and apply it to data from filmed drops of two real slinkies. The modification of the model is the inclusion of a finite time for collapse of the turns of the slinky behind the collapse front propagating down the slinky during the fall. The new finite-collapse time model achieves a good qualitative fit to the observed positions of the top of the real slinkies during the measured drops. The spring constant k for each slinky is taken to be a free parameter in the model. The best-fit model values for k for each slinky are approximately consistent with values obtained from measured periods of oscillation of the slinkies.