The main parameters
Just to be clear, we are only talking about
fault ratings (not rated current). On this, it's probably easiest to
start of with the IEC definition of the relevant ratings:
Icu -
ultimate short-circuit breaking capacity
a breaking capacity for which the prescribed conditions according to a specified test sequence do not include the capability of the circuit-breaker to carry its rated current continuously
a breaking capacity for which the prescribed conditions according to a specified test sequence do not include the capability of the circuit-breaker to carry its rated current continuously
Ics -
service short-circuit breaking capacity
a breaking capacity for which the prescribed conditions according to a specified test sequence include the capability of the circuit-breaker to carry its rated current continuously
a breaking capacity for which the prescribed conditions according to a specified test sequence include the capability of the circuit-breaker to carry its rated current continuously
Icw -
rated short-time withstand current
The rated short-time withstand current of a circuit-breaker is the value of short-time withstand
current assigned
The rated short-time withstand current of a circuit-breaker is the value of short-time withstand
current assigned
Icm -
short-circuit breaking (or making) capacity
a breaking (or making) capacity for which the prescribed conditions include a short circuit
a breaking (or making) capacity for which the prescribed conditions include a short circuit
What does it all
mean?
While the definitions are pretty straight
forward, perhaps a little discussion is worthwhile.
Icu is
really the maximum perspective fault which a circuit breaker can clear (with
the fault current being expressed as rms for ac). This is verified by
testing in accordance with the standard and is applicable at a specific set of
electrical and environmental conditions. If these conditions change then
it may be necessary to derate the circuit breaker. After clearing a fault
the circuit breaker does not have to remain serviceable and could be dangerous
to operate. This point is particularly important in circuit breakers when
the Ics is
lower than the Icu.
Difference between
Icu and
Ics
When tested against the standard, circuit
breakers under go the following tests:
Icu is
subject to an O-t-CO sequence. The breaker is then certified safe by a simple
dielectric test.
Ics is
subject to an O-t-CO-t-CO sequence. The breaker is then subject to both
dielectric withstand and temperature rise tests.
O
|
-
|
breaking operation
|
CO
|
-
|
making operation followed by breaking operation
|
t
|
-
|
time interval (short as possible, but minimum of
3 minutes)
|
Tests are carried out at the specified fault
current.
Ics is
the maximum perspective fault current which the circuit breaker can clear and
still remain serviceable. The standard does allow some minor welding of
the contacts to take place, so after a large fault it would still be necessary
to inspect the breaker. When specified as a percentage of Ics, the
standard proposes ranges of 25%, 50%, 75% and 100%.
Icw is
the perspective fault withstand rating (rms for ac). Circuit breakers may
be subject to through fault which they are not intended to clear. While
not clearing these faults, the breaker will still need to withstand the thermal
and mechanical stress imposed by the fault current. The longer a fault is
present the more the effects build up and Icw always
has a time element associated with it (i.e. 50 kA for 1 second). The
standard specified preferred time ranges of 0.05, 0.1, 0.25, 0.5 and 1 second
(although 3 seconds is also often used in practice).
Icm is
the peak current which the circuit breaker can safely break or make. It
is expressed as the maximum perspective peak current at a rated voltage,
frequency and power factor and is always greater than Icu.
From a safety aspect this is particularly important as it will be the primary
mechanism to protect the operator if the circuit breaker is closed on to a
fault.
All ratings are derived under specific
electrical and environmental conditions and are verified with the circuit
breaker in free air. As soon as the breaker is enclosed in in any kind of
panel or cabinet the ratings change and need to be re-assessed as part of the
assembly testing.
Applying the
ratings
To end the post, a short discussion on
applying the ratings in selecting a circuit breaker.
It should now be
obvious that all the fault parameters need to be considered in selecting the
correct circuit breaker. I think a lot of people reading this have seen
specification clauses like, "circuit breakers shall be rated at 50 kA for
3 seconds", with no other details. When I see statements like this
my first impression (rightly or wrongly), is that I'm reading a poor
specification. I would encourage everyone to be specific in their
specification of what they require and address Icu, Ics, Icw and
Icm as
part of the specification.
I've also noticed
that in general for most of the big manufacturers the majority of their ranges
have an Ics equal
to the Icu.
If I'm presented with a breaker where this is not the case, I immediately
become sceptical on the quality of the device. The device may well be
suitable for the application, but I would be more vigilant on my appraisal of
the circuit breaker. I tend always specify that the Ics should
equal the Icu - to my
mind, what is the point of a circuit breaker if it can't be readily reused
after tripping.
Something else to
bear in mind is that the rating vary depending on the voltage. For low
voltage, we are talking anything from 1000 V down to zero. The lower the
voltage the higher the rating (for example, a Schneider NW12 H2 breaker has an
Icu =
100 kA at 415 V, and this drops to 85 kA at 525 V). Icw is
also dependent on time (the longer the fault the lower will be the
rating). Often Icm is larger
than Icu or
Ics -
make sure you are looking at the right figures and if you are interested in the
Icu it
should be Icu you are
being shown and not Icm.
As a final bit of advice - always consult
manufacturers catalogues and technical data. Manufacturer's produce a
whole range of devices, and you need to select the correct one for your
application. There is no point paying for higher rating if you don't need
to. At the same time compromising on ratings to have a cheaper circuit
breaker jeopardizes safety and operational reliability.Courtesy : Steven McFadyen, myelectrical.com
No comments:
Post a Comment