Limits. We all have them. As a matter of fact, just about everything has limits. An equalizer, of sorts, is electricity. A good jolt will definitely put a human down. In the electronics world, machines are fried on a usual basis because of poor planning in regards to protection. One solution is an uninterruptible power supply (UPS) system, depending of course on your needs.
AC motors are no different. In an article written by Edvard at the Electrical Engineering Portal, motor limits are pretty pronounced:
Every electric motor has operating limits. Overshooting these limits will eventually destroy it and the systems it drives, the immediate effect being operating shutdown and losses. A short circuit is a direct contact between two points of different electric potential:
– Alternating current: phase-to-phase contact, phase-to-neutral contact, phase-to-ground contact or contact between windings in a phase,
– Direct current: contact between two poles or between the ground and the pole insulated from it.
This can have a number of causes: damage to the varnish insulating the conductors, loose, broken or stripped wires or cables, metal foreign bodies, conducting deposits (dust, moisture, etc.), seepage of water or other conducting fluids, wrong wiring in assembly or maintenance.
A short circuit results in a sudden surge of current which can reach several hundred times the working current within milliseconds. A short circuit can have devastating effects and severely damage equipment. It is typified by two phenomena.
The two phenomena referred to are thermal and electrodynamic:
A thermal phenomenon corresponding to the energy released into the electrical circuit crossed by the short circuit current I for at time t based on the formula I2t and expressed as A2s. This thermal effect can cause:
- Melting of the conductor contacts,
- Destruction of the thermal elements in a bi-metal relay if coordination is type 1,
- Generation of electrical arcs,
- Calcination of insulating material,
- Fire in the equipment.
An electrodynamic phenomenon between conductors producing intensive mechanical stress as the current crosses and causing:
- Distortion of conductors forming the motor windings,
- Breakage of the conductors’ insulating supports,
- Repulsion of the contacts (inside the contactors) likely to melt and weld them.
These results are dangerous to property and people. It is therefore imperative to guard against short circuits with protection devices that can detect faults and interrupt the short circuit rapidly, before the current reaches its maximum value.
What can protect electric motors from such phenomena? Fuses and circuit breakers.
They are mounted:
- On special supports called fuse holders,
- Or on isolators in the place of sockets and links.
Note that trip indicator fuse cartridges can be wired to an all-pole switching device (usually the motor control contactor) to prevent single-phase operation when they melt.
The fuses used for motor protection are specific in that they let through the over-currents due to the magnetizing current when motors are switched on. They are not suitable for protection against overload so an overload relay must be added to the motor power supply circuit. In general, their size should be just above the full load current of the motor.
And, of course, circuit breakers:
Magnetic circuit breakers
These circuit breakers protect plant from short circuits within the limits of their breaking capacity and by means of magnetic triggers (one per phase). Magnetic circuit breaking is all-pole from the outset: one magnetic trigger will simultaneously open all the poles.
For low short-circuit currents, circuit breakers work faster than fuses. This protection complies with the IEC 60947-2 standard. To break a short-circuit current properly, there are three imperatives:
- Early detection of the faulty current,
- Rapid separation of the contacts,
- Breakage of the short-circuit current.
Most magnetic circuit breakers for motor protection are current-limiting devices and so contribute to coordination. Their very short cut-off time breaks the short-circuit current before it reaches its maximum amplitude.
This limits the thermal and electrodynamic effects and improves the protection of wiring and equipment.
Whatever your situation, ensure that your AC motors have something that prevents you from discovering the limit your equipment has.