Application Note

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3 Fluke Corporation Troubleshooting power harmonics

Symptoms of harmonics usually

show up in the power distribu-

tion equipment that supports the

non-linear loads. There are two

basic types of non-linear loads:

single-phase and three-phase.

Single-phase, non-linear loads

are prevalent in offices, while

three-phase loads are wide-

spread in industrial plants.

Each component of the power

distribution system manifests

the effects of harmonics a little

differently, yet all are subject to

damage and inefficient perfor-

mance if not designed to handle

electronic loads.

Neutral conductors

In a three-phase, four-wire

system, neutral conductors can

be severely affected by non-

linear loads connected to the 120

V branch circuits. Under normal

conditions for a balanced linear

load, the fundamental 60 Hz

portion of the phase currents will

cancel in the neutral conductor.

In a four-wire system with

single-phase, non-linear loads,

certain odd-numbered harmon-

ics called triplens—odd multiples

of the third harmonic: 3rd, 9th,

15th, etc—do not cancel, but

rather add together in the neutral

conductor. In systems with many

single-phase, non-linear loads,

the neutral current can actually

exceed the phase current. The

danger here is excessive over-

heating because, unlike phase

conductors, there are no circuit

breakers in the neutral conductor

to limit the current.

Excessive current in the neu-

tral conductor can also cause

higher-than-normal voltage

drops between the neutral con-

ductor and ground at the 120 V

outlet.

Circuit breakers

Common thermal-magnetic

circuit breakers use a bi-metallic

trip mechanism that responds to

the heating effect of the circuit

current. They are designed to

respond to the true-rms value of

the current waveform and will

trip when the trip mechanism

gets too hot. This type of breaker

has a good chance of protect-

ing against harmonic current

overloads.

A peak-sensing, electronic trip

circuit breaker responds to the

peak of current waveform. As a

result, it won’t always respond

properly to harmonic currents.

Since the peak of the harmonic

current is usually higher than

normal, this type of circuit

breaker may trip prematurely at a

low current. If the peak is lower

than normal, the breaker may

fail to trip when it should.

Bus bars and

connecting lugs

Neutral bus bars and connecting

lugs are sized to carry the full

value of the rated phase current.

They can become overloaded

when the neutral conductors are

overloaded with the additional

sum of the triplen harmonics.

Electrical panels

Panels that are designed to carry

60 Hz currents can become

mechanically resonant to the

magnetic fields generated by

higher frequency harmonic

currents. When this happens,

the panel vibrates and emits a

buzzing sound at the harmonic

frequencies.

Telecommunications

Telecommunications systems

often give you the first clue to

a harmonics problem because

the cable can be run right next

to power cables. To minimize

the inductive interference from

phase currents, telecommunica-

tions cables are run closer to the

neutral wire.

Triplens in the neutral conduc-

tor commonly cause inductive

interference, which can be heard

on a phone line. This is often the

first indication of a harmonics

problem and gives you a head

start in detecting the problem

before it causes major damage.

Transformer

Commercial buildings commonly

have a 208/120 V transformer

in a delta-wye configuration.

These transformers commonly

feed receptacles in a commer-

cial building. Single-phase,

non-linear loads connected to

the receptacles produce triplen

harmonics, which add up in the

neutral. When this neutral cur-

rent reaches the transformer, it is

reflected into the delta primary

winding where it causes over-

heating and transformer failures.

Another transformer problem

results from core loss and copper

loss. Transformers are normally

rated for a 60 Hz phase current

load only. Higher frequency har-

monic currents cause increased

core loss due to eddy currents

and hysteresis, resulting in more

heating than would occur at the

same 60 Hz current.

These heating effects demand

that transformers be derated for

harmonic loads or replaced with

specially designed transformers.

Effects of harmonic currents

120 V Branch Circuits

208/480 Volt Transformer

Secondary

Primary

Neutral