Cafeteria plate dispensers reveal facts about atoms, in this Moment of Science®.
You're in line at a cafeteria. You pass a stainless-steel cart that presents several stacks of plates. You take a plate off the top of one stack. The other plates in the stack rise from below just far enough to present the next plate at the same height as the one you just took!
Underneath each stack of plates is a spring whose tension is adjusted to keep the top plate level with the top of the cart. Once the adjustment is made, the top plate will always be level with the top of the cart, no matter how many plates are in the stack.
Those cafeteria plate dispensers cleverly exploit a general property of springs: if you put twice as much force on a spring, it compresses, or stretches, twice as far. If you put twenty plates on the stack, their weight compresses the spring just twice as far as the weight of ten plates.
This property of springs was discovered about 300 years ago by the English physicist Robert Hooke. Hooke wrote, "as the tension, so the force." Robert Hooke noticed this principle at work in all kinds of devices that rely on springy materials: spring scales, bows, watches, and the vibrating parts of musical instruments.
In the twentieth century we've come to realize that this relationship, now called Hooke's Law, is a result of forces between atoms in solid material.
If two atoms in a metal are pulled apart, they pull on each other. If you separate the atoms more, the force between them increases, in exact proportion. This is true as long as you don't pull the atoms too far.
Because of this pervasive relationship between atoms, just about all springs compress or stretch twice as far if you load them with twice the force. And because of that, cafeteria plate dispensers keep the top plate level with the top of the cart, no matter how many plates are in the stack.
Read more
- Why is it so easy to break a coffee cup?
- The importance of time when navigating deep space
- Why we can't walk through walls
Sources
- Quotation from Hooke's treatise in the anthology Moments of Discovery, vol. 1, ed. George Schwartz and Philip W. Bishop (1958)
- R.P. Feynman, The Feynman Lectures on Physics, p. I-12-6 (1963)
Cafeteria plate dispensers reveal facts about atoms, in this Moment of Science®.
You're in line at a cafeteria. You pass a stainless-steel cart that presents several stacks of plates. You take a plate off the top of one stack. The other plates in the stack rise from below just far enough to present the next plate at the same height as the one you just took!
Underneath each stack of plates is a spring whose tension is adjusted to keep the top plate level with the top of the cart. Once the adjustment is made, the top plate will always be level with the top of the cart, no matter how many plates are in the stack.
Those cafeteria plate dispensers cleverly exploit a general property of springs: if you put twice as much force on a spring, it compresses, or stretches, twice as far. If you put twenty plates on the stack, their weight compresses the spring just twice as far as the weight of ten plates.
This property of springs was discovered about 300 years ago by the English physicist Robert Hooke. Hooke wrote, "as the tension, so the force." Robert Hooke noticed this principle at work in all kinds of devices that rely on springy materials: spring scales, bows, watches, and the vibrating parts of musical instruments.
In the twentieth century we've come to realize that this relationship, now called Hooke's Law, is a result of forces between atoms in solid material.
If two atoms in a metal are pulled apart, they pull on each other. If you separate the atoms more, the force between them increases, in exact proportion. This is true as long as you don't pull the atoms too far.
Because of this pervasive relationship between atoms, just about all springs compress or stretch twice as far if you load them with twice the force. And because of that, cafeteria plate dispensers keep the top plate level with the top of the cart, no matter how many plates are in the stack.