- #1
Aswin Sasikumar 1729
- 19
- 0
Is it possible to have a purely parallel magnetic circuit in any case?(it should not be a series or series-parallel circuit)
Sure. Just use Google Images to search for Parallel Magnetic Circuit. Here is a typical image that you will see:Aswin Sasikumar 1729 said:Is it possible to have a purely parallel magnetic circuit in any case?(it should not be a series or series-parallel circuit)
Well then can you use Google Images to show us what you are asking about?Aswin Sasikumar 1729 said:Sorry sir but this is not a purely parallel one.This is a series parallel circuit.
Yes I know you may oppose my statement,may be.But in a pure parallel circuit it must be coreless where the coil is wounded...I may not able to clarify it properly.But this is my best effort.sorry
In fact my teacher told that there doesn't exist any magnetically parallel circuit.since there is no matter which has relative permeability as zero.So my real question is simply asking whether there is any material with relative permeability as zero...berkeman said:Well then can you use Google Images to show us what you are asking about?
You will always have the permeability of free space μo. If electrons are moving there will always be a magnetic field. Theoretically, that field covers the entire universe and couples with electrons everywhere.Aswin Sasikumar 1729 said:is any material with relative permeability as zero
I sense some Reluctance,berkeman said:Well then can you use Google Images to show us what you are asking about?
A magnetic circuit is a closed path or loop through which magnetic flux flows. It is made up of a ferromagnetic material, such as iron, and can be used to guide and control the flow of magnetic fields.
A magnetic circuit works by using a ferromagnetic material to concentrate and redirect the magnetic field. This allows for more efficient use of the magnetic flux and can increase the strength of the magnetic field in a specific area.
The main components of a magnetic circuit are a ferromagnetic core, a source of magnetic energy (such as a magnet or electromagnet), and an air gap. Additional components may include coils, windings, and electrical connections.
Magnetic circuits have a wide range of applications, including in motors, transformers, generators, and other electrical devices. They are also used in magnetic sensors, magnetic recording devices, and magnetic levitation systems.
Magnetic circuits are designed and analyzed using principles of electromagnetism, such as Ampere's law and Faraday's law. Computer simulations and modeling techniques are also commonly used to optimize the design of magnetic circuits for specific applications.