The digital protective
relay is a
protective relay that uses a
microprocessor to analyze power system voltages, currents or other process quantities for the purpose of detection of faults in an electric power system or industrial process system. A digital protective relay may also be called a "numeric protective relay".
Input processing Low
voltage and low
current signals (i.e., at the secondary of a
voltage transformers and
current transformers) are brought into a
low pass filter that removes
frequency content above about 1/3 of the
sampling frequency (a relay
A/D converter needs to sample faster than twice per cycle of the highest frequency that it is to monitor). The
AC signal is then sampled by the relay's
analog-to-digital converter from 4 to 64 (varies by relay) samples per power system cycle. As a minimum, magnitude of the incoming quantity, commonly using
Fourier transform concepts (
RMS and some form of averaging) would be used in a simple relay function. More advanced analysis can be used to determine
phase angles,
power,
reactive power,
impedance,
waveform distortion, and other
complex quantities. Only the fundamental component is needed for most protection algorithms, unless a high speed algorithm is used that uses subcycle data to monitor for fast changing issues. The sampled data is then passed through a low pass filter that numerically removes the frequency content that is above the
fundamental frequency of interest (i.e., nominal system frequency), and uses Fourier transform algorithms to extract the fundamental frequency magnitude and angle.
Logic processing The relay analyzes the resultant A/D converter outputs to determine if action is required under its protection algorithm(s). Protection algorithms are a set of logic equations in part designed by the protection engineer, and in part designed by the relay manufacturer. The relay is capable of applying advanced logic. It is capable of analyzing whether the relay should trip or restrain from tripping based on parameters set by the user, compared against many functions of its
analogue inputs, relay contact inputs, timing and order of event sequences. If a fault condition is detected, output contacts operate to trip the associated circuit breaker(s).
Parameter setting The logic is user-configurable and can vary from simply changing front panel switches or moving of
circuit board jumpers to accessing the relay's internal parameter setting webpage via communications link on another computer hundreds of kilometers away. The relay may have an extensive collection of settings, beyond what can be entered via front panel knobs and dials, and these settings are transferred to the relay via an interface with a PC (
personal computer), and this same PC interface may be used to collect event reports from the relay.
Event recording In some relays, a short history of the entire sampled data is kept for oscillographic records. The event recording would include some means for the user to see the timing of key logic decisions, relay I/O (input/output) changes, and see, in an
oscillographic fashion, at least the fundamental component of the incoming analogue parameters.
Data display Digital/numerical relays provide a front panel display, or display on a terminal through a communication interface. This is used to display relay settings and real-time current/voltage values, etc. More complex digital relays will have metering and communication protocol ports, allowing the relay to become an element in a
SCADA system. Communication ports may include
RS-232/
RS-485 or
Ethernet (copper or fibre-optic). Communication languages may include
Modbus,
DNP3 or
IEC61850 protocols. ==Comparison with other types==