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Home / Technical Articles / Using earth & phase directional protection where power flow direction might change

Phase displacement of the current

Directional protection relay is often used in all network parts in which the direction of flow of power might change, notably in the instance of a short circuit between phases or of an earthing fault (single phase fault).

Earth & phase directional protection explained in details
Earth & phase directional protection explained in details

Directional protection is complementary to overcurrent protection, enabling good discrimination of the faulty network section to be achieved in the above mentioned situations.

Active or reactive power protection equipment is used to detect abnormal power flow other than the one due to a short circuit (e.g. In the event of the failure of the prime mover, a generator will continue to run as a synchronous motor, drawing power from the system).

In order to measure a value of power or to localize a fault upstream or downstream of the point at which the current is measured, the phase displacement of the current must be determined relative to a reference variable: the phase to phase voltage for directional phase protection and the residual voltage for directional earthing protection.

This reference variable is called the polarisation quantity.

Contents:

  1. Earth fault (e/f) directional protection
    1. Input variables
    2. Characteristic angle
    3. Principles of detection
      1. Directionalized overcurrent
      2. Measurement of the projection of the current
      3. Measurement of the residual active power
  2. Phase directional protection
    1. Angle of connection, characteristic angle
    2. Principles of detection

1. Earth fault (e/f) directional protection

It is sensitive to the direction of flow of the current to earth. It is necessary to install this type of protection equipment whenever the phase to earth fault current is divided between several earthing systems.

However, this current flow is not only due to the earthing of the network’s neutral, but also due to the phase to earth capacitance of the lines and cables (1 km of 20 kV cable causes a capacitive current flow of around 3 to 4 amps).

Residual directional overcurrent protection, as well as zero sequence active power protection are used to protect feeders with a capacitive current of the same order of magnitude as the earthing fault current.

On these feeders, the phase to earth capacitance is sufficiently high for a zero sequence current to be detected by a nondirectional e/f protection as soon as a phase to earth short circuit occurs, wherever it may be on the network (see Figure 1).

The directional residual current protection equipment (2) does not trip since the current is flowing in the opposite direction.
Figure 1 – The directional residual current protection equipment (2) does not trip since the current is flowing in the opposite direction.

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1.1 Input variables

In earth fault directional protection, the residual current is measured and the residual voltage is most often used as the polarisation quantity. The latter should not be confused with the zero sequence voltage.

Recall that in any three phase system F1, F2, F3, symmetrical component theory defines the zero sequence variable Fh as:

Zero sequence variable

The residual variable Fr is three times greater than the zero sequence variable.

Residual variable


Measuring residual current

The residual current is either measured by three current transformers, one per phase, or by a coil (ring CT) around the three phases.

Measuring the residual current using 3 CT's
Figure 2 – Measuring the residual current using 3 CT’s

The use of three current transformers (see Figure 2) has certain advantages:

  1. CT’s are generally dependable,
  2. It is possible to measure high currents.

But it also has certain disadvantages:

  1. Saturation of the CT’s in the instance of a short circuit or when a transformer is switched on produces a false residual current
  2. In practice, the threshold cannot be set to under 10% of the CT’s rated current.

Measuring using a ring CT (see Figure 3) has the advantage of being very sensitive and the disadvantage of the coil (low voltage insulated) being installed around a non-clad cable to insulate it.

Measuring the residual current using 3 CT's
Figure 3 – Measuring the residual current using 3 CT’s
Measuring residual voltage

Residual voltage is measured by three voltage transformers (VT). Often VT’s with two secondary windings are used (see Figure 4) where one is star connected and enables both phase to neutral and phase to phase voltages to be measured and the other is open delta connected enabling the residual voltage to be measured.

Measuring residual voltage by three voltage transformers (VTs)
Figure 4 – Measuring residual voltage by three voltage transformers (VTs)

If the main VT’s only have one secondary winding are star connected, and grounded, a set of auxiliary VT’s can be used to measure the residual voltage (see Figure 5).

This situation is often encountered when the protection plan for existing installations is upgraded.

Measuring the residual voltage using auxiliary VT's
Figure 5 – Measuring the residual voltage using auxiliary VT’s

It should be noted that certain protection equipment does not require auxiliary VT’s, the equipment itself providing the residual voltage value from the three phase to earth voltages.

The residual voltage is most often used as the polarisation variable for an earth fault directional relay. However, it may also be taken as the current in the installation’s neutral earthing arrangement.

See Figure 6.

The two polarisation modes in directional earthing protection
Figure 6 – The two polarisation modes in directional earthing protection

In theory, both these ways of polarising the protection equipment are equivalent. If Zh is the transformer’s zero sequence impedance and Zn the impedance of the neutral point, the residual voltage, Vr, and the current of the neutral point, In, are related by the following equation (written in complex numbers!):

Vr = (Zh + 3Zn) × In

In practice, polarisation by the neutral point current is only used in networks with an earthing fault current that is both large (several hundreds of Amps) and at the same time much greater than the current due to parasite capacitance on the network.

In this instance the current measurement is more accurate than that of residual voltage, which has a very small value. It can only be used in substations that are near to the neutral earthing connection.

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1.2 Characteristic angle

To determine the direction of the fault, the protection equipment measures the phase displacement between the current and the polarisation variable. If the polarisation variable is not in the axis of symmetry of the wished relay’s action (the characteristic axis, see Figure 7), it is necessary to re-phase it.

This is done by adjusting the characteristic angle.

Operating characteristics of earth fault directional overcurrent protection equipment
Figure 7 – Operating characteristics of earth fault directional overcurrent protection equipment

When designing the protection coordination, the characteristic angle of directional protection equipment must be determined so that any fault in the chosen direction causes a current that falls in the tripping zone and that any current in the other direction causes a current falling outside of this zone.

The characteristic angle depends on the chosen polarisation variable and on the network’s neutral point arrangement (for residual current directional protection equipment). Therefore, the characteristic angle is often adjustable.

To be able to measure the phase displacement between the current and the polarisation variable, it is essential for the latter to be sufficiently large (generally u 0.5 to 2% of the rated value of the variable).

If the polarisation variable is less than this threshold then the protection equipment does not operate, whatever the measured current value.

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1.3 Principles of detection

Three principles of detection exist concurrently and they correspond to various requirements and sometimes to various practices:

  1. Directionalized overcurrent,
  2. Measurement of the projection of the current,
  3. Measurement of the residual active power.

The first two are used for phase and earth fault detection, the last one is specific to earth fault detection with a special neutral point arrangement.

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1.3.1 Directionalized overcurrent (see fig. 10 )

This type of directional relay is made by combining overcurrent protection equipment with an equipment to measure the phase displacement between the current and the polarisation variable.

Tripping is subject to the two following conditions:

  • The current is greater than the threshold, and
  • The phase displacement between the current and the polarisation variable, defined by the characteristic angle, is in the zone between +90° and −90°.

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1.3.2 Measurement of the projection of the current (see fig. 11 )

This type of protection equipment calculates the projection of the current along the characteristic axis. The value obtained is then compared with a threshold in order to determine whether or not to trip.

See Figure 8 below.

The two polarisation modes in directional earthing protection
Figure 8 – The two polarisation modes in directional earthing protection

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1.3.3 Measurement of the residual active power

This type of protection equipment actually measures the residual active power and the threshold is expressed in Watts. It must be designed to avoid any spurious tripping caused by measurement inaccuracy in the instance of a strong capacitive residual current (strong residual reactive power);

The operating zone is limited as shown in Figure 9.

To detect earthing faults, the most universal principle is that of measuring the projection of the current. The use of directionalized overcurrent relays is not suited to all neutral point arrangements.

Operating characteristics of protection equipment measuring the zero sequence active power
Figure 9 – Operating characteristics of protection equipment measuring the zero sequence active power

Protection equipment measuring the residual active power is restricted to use with compensated neutral point arrangements in competition with current projection type relays.

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2. Phase directional protection

It is installed to protect two connections operated in parallel, a loop or a network component connected to two power sources (see Figure 10).

The directional protection equipment (1) is tripped since the direction of current flow is abnormal
Figure 10 – The directional protection equipment (1) is tripped since the direction of current flow is abnormal

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2.1 Angle of connection, characteristic angle

More often than not, this type of protection equipment is two phase comprising two independent, single phase elements. Sometimes three-phase protection equipment must be used.

For each monitored phase, the relay measures its current magnitude, and then uses a phase to phase voltage as the polarisation variable. The phase to neutral voltage is not used since it varies greatly when a fault occurs to earth, due to the displacement effect of the neutral point (residual voltage).

When the relay measures the current in phase 1, the polarisation voltage most often used is V2-V3. The protection equipment’s angle of connection is then said to be 90° (see Figure 11).

A relay mesuring the current I1 and the voltage V2-V3 has a 90° relay connection
Figure 11 – A relay mesuring the current I1 and the voltage V2-V3 has a 90° relay connection

Similarly to a directional earthing relay, the characteristic angle of a directional phase relay defines the position of the angular tripping zone. It is the angle between the normal to the tripping plane and the polarisation variable.

In order to be able to measure the fault direction, the polarisation variable (the voltage) must have a sufficiently high value. In particular, a three-phase fault very close to a directional relay is not detected because all of the phase to phase voltages are zero.

To obtain the direction of this type of fault, the protection system must use a memory voltage.

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2.2 Principles of detection

Phase directional relays function either as directionalized (see Figure 12) overcurrent element, or by measuring the projection of the current on the characteristic axis.

Although relays functioning on both principles exist on the market, the directional overcurrent relay should be preferred.

Operating characteristics of directional overcurrent protection equipment
Figure 12 – Operating characteristics of directional overcurrent protection equipment

Co-ordinating overcurrent protection equipment is much easier since the detection threshold is independent of the current’s phase.

The power measurement is not used to detect short circuits. Power is not a good fault detection criteria because in the instance of a fault between phases the nearer the fault is the lower its value.

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Source: Directional protection equipment by P. Bertrand (Schneider Electric)

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Edvard Csanyi

Electrical engineer, programmer and founder of EEP. Highly specialized for design of LV/MV switchgears and LV high power busbar trunking (<6300A) in power substations, commercial buildings and industry facilities. Professional in AutoCAD programming.

4 Comments


  1. António Carlos
    Jul 11, 2020

    Great explanation!


  2. suresh chandra padhy
    Nov 18, 2019

    Please clarify me what is the tripping zone,when
    1) When ROA=80 degree and RCA= 55 degree for a directional forward over current relay
    2) When RCA=65 degree for a directional forward earth fault protection


  3. Alberto morada
    Jun 20, 2019

    I’m 6months training skills electrical for lighting and auxiliary outlet.i like to read more article about electrical that’s why I’m here.thank you for the reading article…


  4. Zahoor
    Jun 17, 2019

    Sir I satisfied. Please send me your WhatsApp number. I have many problems in power plant.

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