Experiment with heated stretched springs.

In summary, when a spring made of steel is stretched, potential energy is stored in the spring due to tension. Heating the spring up to 700 degrees Celsius causes the tension to disappear, and the spring will remain permanently stretched. This is because the heat allows the molecules to reposition themselves, releasing stresses and settling on a new position of minimum potential energy. This process is known as annealing, and 700 degrees is the annealing temperature for steel. When the spring is heated, it will release the same amount of energy that was used to stretch it.
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I have a spring made of steel. The spring is stretched out, and kept in that position. There is now potential energy in the stretched spring due to tension. If I heat the spring up to 700 degrees celcius, the tension in the stretched spring disappear, and when the springs cools down it is permanently stretched, and I must apply energy to compress it into initial shape.

Where did the potential energy in the stretched spring go? Did I destroy energy or what happend?

Vidar
 
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  • #2
do you know where the springness of a spring comes from, in the first place?

it has to do with the fact that it is a solid and the fixed position of its molecules.

when you stretch the spring and heat it up to a certain temperature...you are basically 'melting' it a bit and putting heat into the system to allow molecules to re-position (re-distant) themselves, release stresses and settle on a new position of minimum potential energy.

you may want to read up on metallurgical processes like annealing.

and yes, 700 degrees is just about the annealing temperature for steel.
 
  • #3
gsal said:
do you know where the springness of a spring comes from, in the first place?

it has to do with the fact that it is a solid and the fixed position of its molecules.

when you stretch the spring and heat it up to a certain temperature...you are basically 'melting' it a bit and putting heat into the system to allow molecules to re-position (re-distant) themselves, release stresses and settle on a new position of minimum potential energy.

you may want to read up on metallurgical processes like annealing.

and yes, 700 degrees is just about the annealing temperature for steel.
Does this mean that the metal will release its tension as heat? Say I use 1J to stretch the spring, then the spring release 1J of heat when I heat it up?

Vidar
 
  • #4
Yep.
 
  • #5
, thank you for sharing your experiment with heated stretched springs. It is an interesting and important area of study in the field of materials science. In response to your question, the potential energy in the stretched spring did not disappear or get destroyed. Instead, it was converted into thermal energy when the spring was heated to 700 degrees Celsius. This thermal energy caused the atoms in the steel to vibrate more rapidly, resulting in the spring losing its tension and becoming permanently stretched.

When the spring cools down, the thermal energy is released, but the atoms have already shifted into a new equilibrium state, causing the spring to maintain its stretched shape. In order to restore the spring to its initial shape, energy must be applied to overcome the new equilibrium and compress the atoms back into their original positions.

This experiment demonstrates the principle of energy conservation, where energy is neither created nor destroyed, but can be converted from one form to another. In this case, the potential energy in the stretched spring was converted into thermal energy, but the total amount of energy remains the same. This concept is crucial in understanding the behavior of materials and how energy is transferred and transformed within them. Thank you for sharing your findings and contributing to the advancement of scientific knowledge.
 

Related to Experiment with heated stretched springs.

1. How does temperature affect the length of a stretched spring?

Temperature can affect the length of a stretched spring by changing the molecular structure of the material. As temperature increases, the molecules in the spring will vibrate more vigorously, causing the spring to expand and increase in length. Conversely, as temperature decreases, the molecules will slow down and the spring will contract and decrease in length.

2. What type of material is best for conducting experiments with heated stretched springs?

The best material for conducting experiments with heated stretched springs is a metal alloy, such as steel or aluminum. These materials have high thermal conductivity, meaning they can quickly and evenly distribute heat throughout the spring, allowing for more accurate and consistent results.

3. How can I control the temperature of the spring during the experiment?

There are several ways to control the temperature of the spring during the experiment. One method is to use a thermometer and heat source, such as a Bunsen burner or hot plate, to directly heat the spring. Another method is to submerge the spring in a temperature-controlled liquid, such as water or oil. Additionally, you can use a heating element, such as an electric coil, to maintain a consistent temperature around the spring.

4. What safety precautions should I take when conducting experiments with heated stretched springs?

When conducting experiments with heated stretched springs, it is important to wear appropriate personal protective equipment, such as heat-resistant gloves and eye protection. You should also have a fire extinguisher nearby in case of any accidents. It is also important to follow proper handling and disposal procedures for any chemicals or materials used in the experiment.

5. What are some potential applications of experiments with heated stretched springs?

Experiments with heated stretched springs have various applications in fields such as materials science, engineering, and physics. They can be used to study the effects of temperature on different materials, to understand the behavior of springs in different environments, and to develop new materials with specific thermal properties. They can also be used in practical applications, such as in the design and testing of thermal expansion components in machines and structures.

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