A magnet falls slower in a copper pipe because the magnetic field generated by the moving magnet induces an electric current in the copper pipe, creating a magnetic field that opposes the magnet's motion, causing resistance and slowing it down.
When a magnet is dropped through a copper pipe, it creates a changing magnetic field. This changing magnetic field induces an electric current in the copper pipe through electromagnetic induction. This demonstrates how a moving magnet can generate electricity in a conductor, showcasing the concept of electromagnetic induction.
I don't know whether this really is the case. But if it is, I can imagine the moving magnet inducing currents in the pipe, resulting in movement energy being lost. (The currents will induce a magnetic field that opposes the movement.)
A copper pipe would be better as a conductor due to copper's high electrical conductivity. It would allow electric current to flow efficiently through the pipe, making it a good choice for applications where electrical conductivity is important.
Copper is often used for the coil in a gas pipe because it has good thermal conductivity, meaning it can efficiently transfer heat from the hot gases. Copper is also resistant to corrosion and can withstand high temperatures, making it a suitable material for this purpose. Additionally, copper is malleable, which allows for easy shaping and installation of the coil in the pipe system.
A copper pipe would work better as a conductor than an insulator. Copper is a metal known for its high electrical conductivity, meaning it allows electricity to flow easily through it. This makes copper pipes ideal for applications where conductivity is important, such as in electrical wiring.
This is an aspect of Lenz's law. Copper is a non magnetic substance but is a conductor. When a magnet moves through the copper pipe it induces a current known as eddy currents. There will be a magnetic field created by the current. According to Lenz's law it will oppose the motion or change which is producing it. This results in an attractive force between the magnet and the copper pipe in which a current is induced by the falling magnet. The plastic rod is not conducting and hence it will not affect the fall.
When a magnet is dropped through a copper pipe, it creates a changing magnetic field. This changing magnetic field induces an electric current in the copper pipe through electromagnetic induction. This demonstrates how a moving magnet can generate electricity in a conductor, showcasing the concept of electromagnetic induction.
Galvanized pipe will be silver/gray color. Copper will be copper. Use a magnet, it'll stick to galvanized pipe but not to copper. Drinking water lines should not be black steel pipe.
I don't know whether this really is the case. But if it is, I can imagine the moving magnet inducing currents in the pipe, resulting in movement energy being lost. (The currents will induce a magnetic field that opposes the movement.)
I am sorry, but can you PLEASE rephrase your question? Can WHAT be used for copper pipe? When? How? Why?
Unless a magnet dropped in a non-ferrous pipe is stopped by some imperfection in the pipe surface itself, it will not be stopped because a non-ferrous surface will not cause a magnet to cling to it.
Grooved method? Threads on the end of the pipe? There is no tube or pipe in copper with threads. You can end a copper pipe with a connection that is threaded to accept steel pipe.
It is very easy to damage any copper pipe.
YOU thread or braze copper pipe Copper tubling you solder, braze, flaire, compression ring, mechincal joints
no
Copper pipe was common anywhere in US.
It is probably referring to the type of fitting. A fitting that is soldered to a copper pipe. It is called sweating when you use solder and a torch to connect copper pipe together or attach fittings to copper pipe.