Study untangles theory of why laces loosen
SAN FRANCISCO — A new study shows why your shoelaces may keep coming untied.
It suggests that a double whammy of stomping and whipping forces acts like an invisible hand, loosening the knot and then tugging on the free ends of your laces until the whole thing unravels.
Using a slow-motion camera and a series of experiments, the study by mechanical engineers at the University of California, Berkeley, and published this week in the journal Proceedings of the Royal Society London A shows that shoelace knot failure happens in a matter of seconds, triggered by a complex interaction of forces.
“When you talk about knotted structures, if you can start
Christine Gregg, study co-author and graduate student
to understand the shoelace, then you can apply it to other things, like DNA or microstructures, that fail under dynamic forces,” said Christopher Daily-Diamond, study co-author and a graduate student at Berkeley.
“This is the first step toward understanding why certain knots are better than others.”
There are two ways to tie the common shoelace bow tie knot, and one is stronger than the other.
The strong version of the knot is based on a square knot: two lace crossings of opposite handedness on top of each other. The weak version is based on a false knot; the two lace crossings have the same handedness, causingthe knot to twist instead of lying flat when tightened.
Designed to develop a baseline understanding of the mechanics of how a shoelace bow tie knot comes untied under dynamic forces and claimed to be more than an example of science answering a seemingly obvious question, the study shows that both versions fail in the same way, and lays the groundwork for future investigation into why the two similar structures have different structural integrities.
The first step was to record the process of a shoelace knot untying in slow motion.
Study co-author and graduate student Christine Gregg, a runner, laced up a pair of running shoes and ran on a treadmill while her colleagues filmed her shoes.
The researchers found that when running, the foot strikes the ground at seven times the force of gravity. The knot stretches and then relaxes in response to that force.
As the knot loosens, the swinging leg applies an inertial force on the free ends of the laces, which rapidly leads to a failure of the knot in as few as two strides after inertia acts on the laces.
As for the fact that when a person goes walking or running, their shoelaces don’t always come untied, as tightly tied laces can require more cycles of impact and leg swinging to cause knot failure than one might experience in a day’s worth of walking or running, the researchers acknowledged that more research is needed to tease apart all the variables involved in the process.
Some laces might be better than others for tying knots, but the fundamental mechanics causing them to fail is the same.”