HT instruments VEGA78 User Manual

VEGA78

EN - 116

10.2.3. Presence of harmonics: causes
Any apparatus that alters the sine wave or uses only a part of such a wave causes
distortions to the sine wave and therefore harmonics.
All current signals result in some way virtually distorted. The most common situation is the
harmonic distortion caused by no-linear loads such as electric household appliances,
personal computers or speed control units for motors. Harmonic distortion causes
significant currents at frequencies that are odd multiples of the fundamental frequency.
Harmonic currents affect considerably the neutral wire of electric installations.
In most countries, the mains power is three-phase 50/60Hz with a delta primary and star
secondary transformers. The secondary generally provides 230V AC from phase to neutral
and 400V AC from phase to phase. Balancing the loads on each phase has always
represented an headache for electric system designers.
Tracing back to ten years ago, in a well balanced system, the vectorial sum of the currents
in the neutral was zero or quite low (in view of the difficulty to get a perfect balance). The
devices were incandescent lights, small motors and other devices that presented linear
loads. The result was an essentially sinusoidal current in each phase and a low current on
the neutral at a frequency of 50/60Hz.
“Modern” devices such as TV sets, fluorescent lights, video machines and microwave
ovens normally draw current for only a fraction of each cycle thus causing non-linear loads
and subsequent non-linear currents. All this generates odd harmonics of the 50/60Hz line
frequency. For this reason, the current in the transformers of the distribution boxes
contains only a 50Hz (or 60Hz) component but also a 150Hz (or 180Hz) component, a
50Hz (or 300Hz) component and other significant components of harmonic up to 750Hz
(or 900Hz) and higher.
The vectorial sum of the currents in a well balanced system that feeds no-linear loads may
still be quite low. However, the sum does not eliminate all current harmonics. The odd
multiples of the third harmonic (called “TRIPLENS”) are added together in the neutral and
can cause overheating even with balanced loads.

10.2.4. Presence of harmonics: consequences
In general, even harmonics, i.e. the 2

nd

, 4

th

etc., do not cause problems. Triple harmonics,

odd multiples of three, are added on the neutral (instead of deleting each other) thus
creating a condition of overheating of the wire which is extremely dangerous.
Designers should take into consideration the three issues given below when designing a
power distribution system that will contain harmonic current:

 The neutral wire must be of sufficient gauge.

 The distribution transformer must have an additional cooling system to continue

operating at its rated capacity when not suited to the harmonics. This is necessary
because the harmonic current in the neutral wire of the secondary circuit circulates in
the delta-connected primary circuit. This circulating harmonic current heats up the
transformer.

 Phase harmonic currents are reflected on the primary circuit and continue back to the

power source. This can cause distortion of the voltage wave so that any power factor
correction capacitors on the line can be easily overloaded.

The 5

th

and the 11

th

harmonic contrast the current flow through the motors making its

operation harder and shortening their average life.
In general, the higher the ordinal harmonic number , the smaller its energy is and therefore
its impact on the devices (except for transformers).