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Learn How To Specify Current Transformers
Learn How To Specify Current Transformers (photo credit: naswgr.net)
Instrument and protection CTs
Curr ent transformers are used to supply information to the protective relays and/or current, power and energy meterin
“instruments”. For this purpose they must supply a secondary current proportional to the primary current flowing
through them and must be adapted to network characteristics: voltage, frequency and current.
They are defined by their ratio, power and accuracy class. Their class (accuracy as a function of CT
load and of overcurrent) is chosen according to the application.
A “protection” current transformer (CT) must saturate sufficiently high to allow a relatively accurate measurement
the fault current by the protection whose operating threshold can be very high. Current transformers are thus expecte
to have an Accuracy Limit Factor (ALF) that is usually fairly high. Note that the associated “relay” must be able to
withstand high overcurrents.
http://electrical-engineering-portal.com/download-center/books-and-guides/schneider-electric/current-transformers-how-to-specifyhttp://electrical-engineering-portal.com/learn-how-to-specify-current-transformers?utm_source=EEP+Monthly+Download+Updates&utm_campaign=77e9126042-Complete_Power_Engineering_Guide12_5_2015&utm_medium=email&utm_term=0_91c70c6fa4-77e9126042-320879933&mc_cid=77e9126042&mc_eid=5681cd642ahttp://electrical-engineering-portal.com/http://electrical-engineering-portal.com/download-center/books-and-guides/schneider-electric/current-transformers-how-to-specifyhttp://electrical-engineering-portal.com/learn-how-to-specify-current-transformers?utm_source=EEP+Monthly+Download+Updates&utm_campaign=77e9126042-Complete_Power_Engineering_Guide12_5_2015&utm_medium=email&utm_term=0_91c70c6fa4-77e9126042-320879933&mc_cid=77e9126042&mc_eid=5681cd642ahttp://electrical-engineering-portal.com/
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An example of a protection CT
An “instrument”current transformer (CT) requires good accuracy around the nominal current value. The metering
instruments do not need to withstand currents as high as the protection relays. This is why the “instrument” CTs, unlik
the “protection” CTs, have the lowest possible Safety Factor (SF) in order to protect these instruments through earlier
saturation.
Some current transformers have secondary windings dedicated to protection and metering. These “instrument” and
“protection” CTs are governed by standard IEC 60044-1 (in France NF C 42-502).
The matching of CTs with protection relays calls for a thorough knowledge of current transformers. The following
section gives a few reminders of CTs corresponding to this use.
Characterisation of CTs
An example of a protection CT //
Rated primary current: 200 A,
Rated secondary current: 5 A.
Its accuracy load: Pn = 15 VA
Its accuracy limit factor is ALF = 10
For I = ALF. In, its accuracy is 5% (5P), (see figure 1)
To simplify, for the protection CT given in example, the ratio
error is less than 5% at 10 In , if the real load consumes 15
VA at In. However these data are not sufficient. Also, it is
useful to know the standard values.
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Figure 1 – Example of the nameplate of a current transformer with two secondaries
12 definitions related to current transformers //
Rated (nominal) primary current I1
Rated (nominal) secondary current I2
Ratio (I1 / I2)
Accuracy load
Rated (nominal) accuracy power Pn
Real power Pr
Accuracy class
Special accuracy class
Real accuracy factor (Fp or Kr)
Accuracy limit factor (ALF or Kn)
Short time withstand current
CT rated voltage
≡ Rated (nominal) primary current I1
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Defined by standards, it is chosen from the discrete values: 10 – 12.5 – 15 – 20 – 25 – 30 – 40 – 50 – 60 – 75 A and
their decimal multiples.
≡ Rated (nominal) secondary current I2
Equals 1A or 5 A.
≡ Ratio (I1 / I
2)
The primary and secondary currents are standard, thus these values are discrete. (Learn more about ratios of
magnetic HV instrument current transformers – Here)
≡ Accuracy load
Load value on which the accuracy conditions are based.
≡ Rated (nominal) accuracy power Pn
Expressed in VA, it is the apparent power supplied to the secondary circuit for the nominal (rated) secondary current
and the accuracy load. The standard values are: 1 – 2.5 – 5 – 10 – 15 – 30 VA .
≡ Real power Pr
In this technical article, it is the power corresponding to the real load consumption of the CT at In.
≡ Accuracy class
This class defines the error limits guaranteed on the ratio and on the phase shift in specified power and current
conditions. For the nominal 5P and 10P classes, the table in figure 6 defines these limits.
Figure 2 // Errors on the module and the phase at nominal current
(according to standard IEC 60044-1)
Accuracyclass
Current error for the nominalcurrent as a %
Phase shift for the nominalcurrent
Composite errors for the accuracy limitcurrent as a %
Minutes Centiradians
5P ± 1 ± 60 ± 1.8 5
10P ± 3 – – 10
≡ Special accuracy class
Class X is a class defined by British standard BS 3938. It must also be defined in the future standard IEC 60044-1
under the name of class PX. This class specifies the minimum value of the knee point voltage Vk of the CT.
It also imposes a maximum value of Rct (CT secondary winding resistance). Sometimes, it
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Figure 3 – Voltages corresponding to different CT classes
specifies the maximum value of the magnetising current Io at knee point voltage.
If we consider the magnetising curve V(Io) of the CT, the knee point voltage Vk is defined as the point on this curv
from which a 10% increase in voltage causes a 50% increase in the magnetising current Io. Class X corresponds to a
better metering accuracy than classes 5P and even more so 10P (see figure 3).
It is always possible to find an equivalence betweena CT defined in class X and a 5P CT or in some
cases even a 10P CT.
≡ Real accuracy factor (Fp or Kr )
This is the ratio between the overcurrent
corresponding to the nominal error and the rated
current of the CT when the real load is different from
the nominal load.
≡ Accuracy limit factor (ALF or Kn)
This is the ratio between the nominal overcurrent
(e.g. 10 In) and the rated current (In).
≡ Short time withstand current
Expressed in kA, this is the maximum current Ith that can be withstood for one second (when the secondary is short-
circuited). It represents the thermal withstand of the CT to overcurrents (the standard values are given by the
standards mentioned in the appendix).
≡ CT rated voltage
This is the rated voltage to which the CT primary is subjected. It is important to remember that the primary is at HV
potential and that one of the terminals of the secondary (which must never be opened) is normally earthed.
Just as for any devices, a maximum withstand voltage for one minute at power frequency and a maximum impulse
voltage withstand are also defined. Their values are defined by the standards.
For example: for a rated voltage of 24 kV, the CT must withstand 50 kV for 1 minute at 50 Hz and 125
kV at the impulse voltage.
CT with several secondaries
Some current transformers may have several secondaries dedicated to protection or to metering. The most typical
cases are CTs with 2 secondaries, more rarely with 3 secondaries. Physically, these CTs group in the same mould the
equivalent of 2 or 3 separate CTs that can have different classes and ratios (see figure 4 below).
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Figure 4 – Manufacturing principle of a CT with 3 secondaries (with 3 windings in
the same mould)
Current transformers – VIDEO sessions
What are CTs and why use them?
CT Polarity
CTR
Wye connected CTs
Delta connected CTs
Current transformer model
Reference // Cahier Technique Schneider Electric no. 194 – Current transformers: how to specify them by Schneider
Electric
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