Generating heat from electricity from friction

In summary, the conversation revolved around the possibility of generating electricity from friction between two conductors and using that electricity to generate heat. While some suggested methods such as using a heat pump or thermoelectric generators, others questioned the practicality and efficiency of such methods. Ultimately, it was determined that using a heat pump or thermoelectric device to generate heat from friction would not be a very efficient or practical solution.
  • #1
hometown23
6
0
I am interested in generating heat manually by rubbing two materials together. I am trying to find the most efficient way to generate the most heat. I've read a little about thermoelectricity where if a current flows in a circuit consisting of two different conductors then one of the junctions is heated and the other is cooled.

My question is, would it be possible to rub two conductors together to generate electricity from friction, and use that electricity to generate heat? I don't need to generate a huge amount of heat, just *more* heat than friction alone would generate.

Thanks.
 
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  • #2
Possible? I don't see why not. I just don't see any practical use for it. Other methods are far better for generating both heat and electricity.
 
  • #3
Sure there are better ways to generate heat. But it's the simplicity of rubbing two items together to generate more heat than expected that I'm trying to demonstrate.
 
  • #5
hometown23 said:
I've read a little about thermoelectricity where if a current flows in a circuit consisting of two different conductors then one of the junctions is heated and the other is cooled.
This works the other way round as well. Heating the junction will cause current to flow.

http://en.wikipedia.org/wiki/Thermopile

There's no reason the heat couldn't be created by friction and the current generated used to operate a separate heater.

I guess the trouble is that you'd be wearing away your junction in direct proportion to how much you used it to generate current.
 
  • #6
Thanks for the input. It got me thinking about some different methods, but I think the biggest hurdle is that I'm trying to do it without an additional power supply or battery.


Curl said:
Use a heat pump. That's what you're looking for:

http://en.wikipedia.org/wiki/Heat_pump

It is far better than the electric effect you mentioned.

Solid state heat pumps are along the lines of what I'm looking for, but they seem to take large amounts of current (1+ Amps) to operate. Could these be useful only using the current generated by rubbing two objects together?


zoobyshoe said:
This works the other way round as well. Heating the junction will cause current to flow.

http://en.wikipedia.org/wiki/Thermopile

It says that the voltage created by a thermopile is only in the range of tens or hundreds of milli-volts. Would additional heat generated by this small voltage be noticable?
 
  • #7
Where does the input energy to do the rubbing come from?

The problem I see with your idea is that heat is the final waste product of most processes and as such, direct heat production is nearly always about 100% efficient. So it really doesn't much matter how you generate it.
 
  • #8
The input energy is manual. Simply rubbing the objects together by hand.

I agree that the waste heat is 100% efficient, but that's why I am considering a simple thermoelectric or heat pump device to give it a boost. The additional heat transferred by the device would make the heat output more than 100% of the input energy.
 
  • #9
hometown23 said:
It says that the voltage created by a thermopile is only in the range of tens or hundreds of milli-volts. Would additional heat generated by this small voltage be noticable?
That's referring to a thermopile as a commercially available electronic component. You can scale them up to any output. As I recall the specific metal combinations used, the area of contact of the dissimilar metals, and the temperature difference between the hot and cold ends are the important factors. Once those are optimized, then you just keep adding them in series like batteries. I once saw a photo of a guy hanging from an iron rod being held by an electromagnet being powered by a thermopile (which was being powered by a propane torch). You can get some current out of them.

But, like Russ says, the original waste heat you have is already at maximum efficiency.
 
  • #10
Just converting work to heat 100% is not the maximum "efficiency" by his definition of efficiency.

Using a heat pump gives more heat than work input, since you can also take thermal energy from the surroundings.

Thermopile is a piece of trash. The classical fluid cycle heat pump is much better.
 
  • #11
Curl said:
Just converting work to heat 100% is not the maximum "efficiency" by his definition of efficiency.

Using a heat pump gives more heat than work input, since you can also take thermal energy from the surroundings.

Thermopile is a piece of trash. The classical fluid cycle heat pump is much better.
A thermopile works on temperature difference. As I said earlier, the amount of electricity generated is dependent on the magnitude of the difference in temperature between the heated junctions and the cooled ones. If he had his "cold side" out in a Minnesota winter, for example he'd generate much more electricity with a given amount of heat friction than if the cold side were in the room with him. He could, in fact, passively generate current by sticking the cold junctions in a snowbank, and keeping the hot side in his armpit.

Hometown, they also have these things now called Thermo-electric generators:

http://www.tegpower.com/

You could buy two and rub them together.
 
  • #12
hometown23 said:
The input energy is manual. Simply rubbing the objects together by hand.

I agree that the waste heat is 100% efficient, but that's why I am considering a simple thermoelectric or heat pump device to give it a boost. The additional heat transferred by the device would make the heat output more than 100% of the input energy.
Oh, I see: you want to use a thermoelectric device as a heat pump...

Well, it could work, but I don't think you could get much from it. Peltier devices are pretty inefficient and using friction to generate electricity is even worse. Why does it have to be friction?
 
  • #13
russ_watters said:
Why does it have to be friction?
And why does it have to be friction generated with his own muscle power? Clearly he has a specific and unusual application in mind.
 
  • #14
My thought is to generate heat in the middle of nowhere using the most basic components. Rubbing two things together seems like the simplest way to generate heat, so I was thinking about how to give it a boost. The theory of heat pumps is great, but you can't readily carry a fluid cycle heat pump around.

Zoobyshoe, Thermo-electric generators may do the trick. Like you said, sticking one end in the snow and the other under your armpit alone gives you current. No rubbing required. I'll have to look into the size, cost, potential output, etc.
 
  • #15
hometown23 said:
I am interested in generating heat manually by rubbing two materials together.

Making fire? Seen it done but there's no future in it I tell you!

And what about the risks and the environmental damage?
166girs.jpg
 
  • #16
hometown23 said:
My thought is to generate heat in the middle of nowhere using the most basic components. Rubbing two things together seems like the simplest way to generate heat, so I was thinking about how to give it a boost. The theory of heat pumps is great, but you can't readily carry a fluid cycle heat pump around.

Zoobyshoe, Thermo-electric generators may do the trick. Like you said, sticking one end in the snow and the other under your armpit alone gives you current. No rubbing required. I'll have to look into the size, cost, potential output, etc.
The snow/armpit thing would only work with thermopiles you engineered yourself, mind you, because you could make the physical separation between the hot and cold junctions as large as you wanted. The pre-made thermoelectric generators have the hot and cold side pretty close to each other. I have read there's a danger of the heat from the hot side overwhelming the cold side in some applications (i.e. where the cold side isn't actively cooled). That shouldn't be a problem in your scenario, but you'll have to do something like set the TEG on the cold ground and sit or lay on the hot side. Same principle, though: use the cold to your advantage.
 
  • #17
epenguin said:
Making fire? Seen it done but there's no future in it I tell you!
Those "fire" demonstrations are all hoaxes. Those are the same guys that hoax easy transportation with "wheels" and who claim you can move a big rock with a stick and a "fulcrum". ThunderSpirit Of The Clouds will strike them dead some day.
 
  • #18
With the TEGs, is the heat "consumed"? In the snow/armpit scenario, would your armpit eventually get cold? There has to be some cost to the current generated, right?

I'll look into this "fire" thing as well.
 
  • #19
hometown23 said:
With the TEGs, is the heat "consumed"? In the snow/armpit scenario, would your armpit eventually get cold? There has to be some cost to the current generated, right?
Yes, you'd be losing body heat to keep the system going but the return you get should prevent you from getting colder.

If you want to dabble with such dangerous modern notions as "fire", I would recommend looking deeply into the "wood gas stove". This is a configuration of tin cans that is engineered to gasify wood and burn the generated gas for heat, cooking, etc. The great advantage of a "wood gas stove" is that it works well with twigs and sticks. You don't need to fell a tree or carry a hatchet with you. Properly made and operated, the result of a burning is charcoal, rather than ash, which can, itself be turned around and burned. (Alternately, you could draw on the walls of your cave with it.)

Just go to YouTube and type "wood gas stove". About a hundred videos will come up.

Once you get the principle down you could design a collapsable one from sheet metal for easy carrying in the back pack. People on YouTube have even made them from heavy duty aluminum foil. It is quite interesting to see someone get a few sticks to burn for a whole half hour with a large flame.
 

1. How does generating heat from electricity from friction work?

Generating heat from electricity from friction involves using the principle of converting kinetic energy into thermal energy. When two surfaces rub against each other, friction is created and some of the kinetic energy from this motion is converted into heat energy.

2. What materials are commonly used to generate heat from electricity from friction?

Materials that are good conductors of electricity and have high friction coefficients are commonly used to generate heat from electricity from friction. Some examples include metals like steel, copper, and aluminum, as well as materials like carbon and graphite.

3. What are the applications of generating heat from electricity from friction?

Generating heat from electricity from friction has many practical applications. It is commonly used in household appliances such as toasters, hair dryers, and electric heaters. It is also used in industrial settings for processes such as welding and metal forging.

4. How efficient is the process of generating heat from electricity from friction?

The efficiency of generating heat from electricity from friction depends on several factors, such as the materials used, the surface area of contact, and the speed of rubbing. In general, it is not as efficient as other methods of generating heat, but it can be a useful and convenient way to produce heat in certain situations.

5. Are there any safety concerns when using generating heat from electricity from friction?

There can be safety concerns when using generating heat from electricity from friction, as the process involves the production of heat and can potentially lead to fires or burns if not used properly. It is important to follow safety precautions and use appropriate protective gear when working with materials that generate heat from friction.

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