General, Current inputs, Current measurement functions – Basler Electric BE1-851 User Manual

SECTION 3 • INPUT AND OUTPUT FUNCTIONS

General

The BE1-851 inputs consist of three-phase current inputs, neutral current inputs, and four contact sensing

inputs. Five general-purpose output contacts and one dedicated, fail-safe alarm output make up the BE1-

851 outputs. Each input and output is isolated and terminated at separate terminal blocks. This section

describes the function and setup of each input and output.

Current Inputs

Secondary current from power system equipment CT is applied to current transformers inside the relay.

These internal transformers step down the monitored current to levels compatible with relay circuitry and

provide isolation. Secondary current from each internal CT is converted to a voltage signal and then

filtered by an analog, low-pass, anti-aliasing harmonic filter.

Current Measurement Functions

The power system analog quantities for phase, neutral, and negative-sequence currents are calculated

and used by all of the current dependent functions of the relay. There is no separate positive or zero-

sequence value calculated. The filter response for phase and neutral calculations can be independently

programmed. Operation of the current measurement function is governed by settings for nominal

frequency, digital signal processing algorithm, current transformer ratio, and normal phase rotation.

Nominal Frequency

Input waveforms are sampled by an analog-to-digital converter at 24 samples per cycle. A nominal

frequency of either 50 or 60 Hz must be selected in order for the analog-to-digital converter to sample

analog quantities at appropriate time intervals to achieve 24 samples per cycle.

Digital Signal Processing

The digital signal processing (DSP) setting governs how the phase and neutral operating quantities are

measured. The negative-sequence current is derived from the phase currents and is not independently

settable. The three choices are Fundamental, RMS, and Average. This is independently settable for the

phase and neutral quantities. Each setting causes the relay to respond differently in the presence of

significant harmonics and for operation at significantly off-nominal frequency. Accuracy characteristics for

each algorithm (Fundamental, RMS, and Average) are shown in Figure 3-1. This figure is for a 60 Hz

nominal system with frequencies between 55 and 65 Hz. A 50 Hz nominal system would have similar

characteristics.
The fundamental setting (F) uses a Fourier filter to extract the fundamental frequency component of the

measured current and reject the harmonic frequency components. This setting is best suited for most

protection purposes due to its superior transient overreach and fast dropout characteristics. It is also

recommended for applications where harmonic rejection is desired. For example, in a neutral circuit

where the third harmonic component is additive and can result in unwanted tripping.
The RMS setting uses a true RMS calculation to include harmonic components of the measured current.

The presence of significant levels of harmonics can cause heating in protected equipment and increased

sensitivity in electro-mechanical devices. This setting is recommended for equipment applications that

require thermal overload protection. It is also recommended for applications where the transient

overreach and sensitivity characteristics provide better coordination with induction disk type overcurrent

protection systems.

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BE1-851 Input and Output Functions

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