DuhBoyChong
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What is Back emf, and supply emf. I have trouble understanding
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What is Back emf, and supply emf. (1 Viewer)
- Thread starter DuhBoyChong
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PhysicsMaths
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In terms of motors, a rotating armature (carrying the rotor coils) that moves through an external magnetic field will cut magnetic field lines, and will hence experience a changing flux. According to Faraday's law (which states EMF is proportional to change in flux/change in time), a changing flux will induce an EMF (known as the supply emf). This EMF will induce a current that creates a magnetic field to oppose the changing flux that induced it in the first place (Lenz's law). The opposition in motion caused by the induced current is known as back emf (because it opposes the supply emf).
To further explain, back emf is necessary to ensure the law of conservation of energy holds. If the induced current flows in a direction to support the motion of the rotor, then it would spin faster and faster (creating energy out of nowhere).
Also note that the net EMF created within the motor is defined as:
net emf = supply emf - back emf
and it's also worth mentioning that as a motor's armature rotates faster, it will experience a greater changing flux, so back emf will increase. Therefore, the net emf within the motor decreases!
*also note that Lenz's law will only apply to systems in a closed circuit. A current carrying rod moving through an external magnetic field will experience no back emf.
To further explain, back emf is necessary to ensure the law of conservation of energy holds. If the induced current flows in a direction to support the motion of the rotor, then it would spin faster and faster (creating energy out of nowhere).
Also note that the net EMF created within the motor is defined as:
net emf = supply emf - back emf
and it's also worth mentioning that as a motor's armature rotates faster, it will experience a greater changing flux, so back emf will increase. Therefore, the net emf within the motor decreases!
*also note that Lenz's law will only apply to systems in a closed circuit. A current carrying rod moving through an external magnetic field will experience no back emf.
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DuhBoyChong
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Thank you sooo much
someth1ng
Retired Nov '14
Just be careful with your wording, it's not correct to say that back emf is there to satisfy the conservation of energy. It's there because there is a change of flux through the ring which produces the back emf which then means the motor will satisfy the law of conservation of energy.
Electromotive Force
http://en.wikipedia.org/wiki/Electromotive_forcelol, like the actual definition
Fizzy_Cyst
Well-Known Member
For HSC sake, EMF = Potential Difference = Voltagelol, like the actual definition
We use all 3 interchangeably
But in real life:
Potential Difference = Voltage but there is a distinction between these and EMF, if I remember correctly
Kaido
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Hmm, just curious, but is this truth?
Yeah. See here: http://en.wikipedia.org/wiki/Voltage#Definition
"Given two points in the space, called A and B, voltage is the difference of electric potentials between those two points."
(And this is what "electric potential" is defined as: http://en.wikipedia.org/wiki/Electric_potential (includes mathematical definition))