Current and voltage sensors as an alternative to traditional CTs and VTs
The current snsors type KECA 80 Cxxx are intended for use in current measurement in medium voltage air insulated switchgear type UniGear ZS1 12/17.5kV
Sensors as alternative
As an alternative for traditional primary current and voltage measurement techniques, the use of sensor technique is gaining field. This technique is typically applied to current and voltage measurement in medium-voltage metal-enclosed indoor switchgears.
There are many undeniable advantages with sensors when compared to the traditional solutions:
- High degree of accuracy
- Personnel safety
- Extensive dynamic range
- Small physical size and weight
- Possibility to combine current and voltage measurement into one physical device with compact dimensions
- Environmental friendliness (less raw material needed)
The measurement of current is based on the Rogowski coil principle. The Rogowski coil is a toroidal coil without an iron core. The coil is placed around the current-carrying primary conductor. The output from the coil is a voltage signal, proportional to the derivative of the primary current.
The signal is then integrated in the secondary device to produce a signal proportional to the primary current wave form.
Since no iron core is employed, no saturating occurs, unlike with traditional current transformers.
The open-circuited traditional current transformer produces dangerous voltages to the secondary side and lead to a serious overloading of the transformer. Since the output from the current sensor is a voltage signal, the open-circuited secondary conditions do not lead to a dangerous situation, neither to human beings nor apparatus.
Figure 1 – Principle of current measurement based on Rogowski coil
The transmitted signal is a voltage:
For a sinusoidal current under steady state conditions the voltage is:
With traditional current transformers, the ratio of the CT is fixed to one value, or in case of multi-ratio CTs, to several values. These values are chosen according to the specific application needs and load currents.
As a result, one, for example medium-voltage primary switchgear, installation usually requires several CT types.
With a current sensor, the situation is simpler, since one type of sensor covers a range of primary currents and in optimum case the whole installation can be covered with one type only.
To give an idea of the secondary-voltage signal level, one fixed point (ratio) inside the rated current range could be 400 A primary value, typically corresponding to 150 mV secondary signal level.
Figure 2 – Example on current sensor’s rated current range
The problems related to saturating iron core in conventional current transformers can be overcome with the sensor technology. The below figure demonstrates the difference between the secondary-signal performance for both traditional current transformer and current sensor.
Figure 3 – Principle comparison of current sensor and current transformer secondary-signal performance as a function of combined error (ε) and primary current (IP)
Due to the compact size of a current sensor (no iron core), there are better possibilities to integrate the measurement devices inside other constructional parts of a metal-enclosed switchgear.
An example of this possibility would be the integration of a sensor inside plug-in-type medium-voltage cable terminations.
Figure 4 – On the left a current sensor inside cable plug-in termination and on the right a current sensor inside conventional housing
The measurement of voltage is based on voltage divider. Two main types are available, namely the capacitive one and the resistive one. The output in both cases is a low-level voltage signal. The output is linear throughout the whole rated measurement range.
The considerations and protection methods against the ferroresonance phenomena, discussed with traditional voltage transformers, are not applicable with voltage sensors.
Figure 5 – Two main principles for voltage sensor implementation
As with current sensors, also with voltage sensors it is possible to cover certain voltage range with one sensor type. To give an idea of the secondary voltage signal level, one fixed point (ratio) inside the rated voltage range could be 20000/?3V primary value, typically corresponding to 2/?3V secondary-signal level.
Figure 6 – Voltage sensor implementations. On the left a dedicated voltage sensor and on the right a sensor located inside a support insulator
The sensor solution being quite compact and space saving, it is possible to combine both current and voltage sensors in one physical device. This device can be part of the switchgear’s mechanical basic construction, having other functions beside the measurement, like being a part of medium-voltage cable termination or busbar support construction.
These features give new possibilities to design switchgear constructions that are built according to specific customer needs and on the other hand they help the standardization work for the bulk type of switchgears.
Figure 7 – A combined current and voltage sensor acting also as a busbar tube support insulator
Conclusion and comparison
The features of the sensor measurement technique compared to the traditional approach are shortly summarized in the figure below.
It could also be asked why the sensor approach has not totally taken over the traditional approach, at least when it comes to medium-voltage indoor switchgear. This is a very valid question and several answers could be given, depending on the viewpoint of the person answering.
Without going into this discussion any deeper, one valid argument is the limited selection of sensor-connectable secondary devices other than protection relays (IEDs).