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Chapter 14: Electromagnetism
Version 0.51
Electromagnetism
An electrical current in a wire produces a magnetic field
Ampere-Turns
The strength of the magnetic field in a coil depends on
Magnitude of the current
Number of turns
Known a the magnetomotive force (mmf)
MMF Formula
MMF = I x N
MMF – magnetomotive force in Amp-turns
I – current in ampreres
N – number of turns in a coil
Amp - turn Examples
Field Intensity
Defined as H
Mmf per unit length
Amp-turns of mmf ÷ length of coil
Unit is the amp-turns per meter.
MMF Examples
Magnetic Polarity
Depends
Flow of the current
Direction of the coil winding
Reversing either changes the polarity of the coil
Coil Magnetic Polarity
Induced Current
When magnetic flux moves across a conductor it forces free electrons in a coil to move, creating electrical current
Induction
Conductor must be perpendicular to the magnetic flux
Magnetic Induction
Faraday’s Law
Amount of induced voltage depends on:
Amount of magnetic flux
Number of turns
Rate of change in the magnetic flux
Faster the flux changes the greater the induced voltage
Faraday’s Law Formula
Relay
Electromechanical device
Operates by induction
Use coil to operate a set of contacts
NC or NO
Relay Diagram
Relay Contacts
Typical Relays
Typical Relays
Relay Applications
Relay Specifications
Contactors
Motor Starter
Recommended