Recommended Practice for Power
Quality Measurements in AC Power Supply Systems
1
Overview
1.1 Scope
This recommended practice
establishes the data acquisition attributes necessary to characterize power quality phenomena. It
establishes the data acquisition attributes necessary to characterize the
electromagnetic phenomena listed in table 2 of IEEE Std. 1159-1995. This guide
includes definitions, instrumentation categories and technical requirements
which are related to the type of disturbance to be recorded.
1.2 Objective
The objective of this
recommended practice is to describe the technical measurement requirements for
each type of disturbance defined in 24 categories of typical characteristics of
power system electromagnetic phenomena found in Table 2 of IEEE Std 1159-1995
(R2001). The intent of this document is
that the measurements of the same signal for any parameter defined herein can
be carried out with two different instruments that will produce matching
results within the specified uncertainty.
The initial publication of
this document covers the category of RMS voltage variations referred to as sags
(or dips) and swells. (Where ever the
word “sag” is used in this document, it can be interchanged with “dip”.) Subsequent revisions will address the
remaining parameters. In particular,
harmonics will be addressed in a manner similar to IEC 61000-4-7 Testing and Measurement Techniques on
Harmonics and Interharmonics Measurements and Instrumentation, for Power Supply
Systems and Equipment Connected. Transients
(surges) will include the works of IEC, UIE, and other references included in
the Bibliography.
2
Definitions
2.1 Background
Some definitions given in
this section have not been fully harmonized with definitions made in other IEEE
standards and IEC documents. Where
several definitions for the same terms exist, they are both included. Before
scheduling the power quality measurement, the user must select the instrument
which meets their needs. This section
addresses the language and the assessment specification which needs to be understood
to communicate with the instrumentation supplier . Also, the user should define their needs clearly. []Without the assessment specification of the
instrument, or with an inappropriate specification, users are unable to assess
the severity level of the disturbance on equipment; this can lead to incorrect
conclusions and costly decisions. Users
should ask suppliers for the complete measurement-instrument specification,
which may include the following information:
·
sampling rate,
·
bandwidth amplitude/frequency
·
accuracy []
·
precision (
·
resolution
(signal-to-noise ratio or effective bits)
·
differential mode
argument and amplitude accuracy,
·
common mode rejection
·
anti-aliasing filter
(cut-off frequency, filter order, filter type)
·
window width, (interval
of the sampled signal used for each analysis)
·
number of windows
analysed per second,
·
type of weighted window
used (rectangular, triangular, Blackman, Vincent, …)
·
waveform
synchronization device used (electronic phase locked loop or digital
synchronization),
·
accuracy of the
synchronized device,
·
global time
synchronization method used and its accuracy
·
the common mode rejection ratio,
·
flag when the phase
locked loop is not synchronized
·
flag when hardware or
software error occurs,
·
flag when some
frequency components present in the signal are not recorded,
·
immunity of the
instrument to disturbances in the
supply voltage (transient, voltage sag (dip)s, voltage distortion etc…),
·
operating
environment (temperature, vibration,
humidity)
2.2 IEEE & IEC Definitions
Term
|
Definition |
Source |
Accuracy
|
IEC dictionary and
IEEE 100 |
|
|
|
Accuracy
is the degree of agreement between measured values and the true values (i.e.
closeness to the reality). |
|
|
Aliasing |
The
distortion caused by sampling a signal at an inappropriate rate and which
results in the overlapping of the sidebands around the harmonics of the
sampling frequency in the spectrum of the sample signal. Note.:
A high frequency which exceeds the operating range of the instrument affects
the frequency component in the frequency range of the analysis. IEC has requested use of an anti-aliasing
filter which should attenuate to below 50 dB all frequencies above the
operating range of the instrument.
Observation windows may be flagged during the presence of frequency
components which exceed the operating range of the instrument. If these high frequency components occur
too often, the user may need a wider bandwidth instrument. |
IEC dictionary |
|
Analogsignal |
A
signal in which the characteristic quantity representing information may, at
any instant, assume any value within a continuous interval. Note.
For example, an analog signal may follow continuously the values of another
physical quantity representing information |
IEC dictionary |
|
Anti-aliasing |
Correction
intended to reduce the aliasing. |
IEC dictionary |
|
Bandwidth |
The frequency range over which a given characteristic of a channel does not differ
from a reference value by more than a specified amount or ratio. Note: the
given characteristic may, for example, be the amplitude/frequency, the phase/frequency
or the delay/frequency characteristic.
The
quantitative difference between the limiting frequencies of a frequency
band. For most power quality users
should specify the bandwidth as the frequency for which the maximum
sinusoidal input signal has decreased below the accuracy specified |
|
|
Channel |
Inividual measurement path through an
instrument Note: “Channel” and “phase” are not the
same. A voltage channel is by
definition the difference in potential between two conductors. Phase refers
to a single conductor. A channel may be between two phases on a poly-phase
system, or between a phase and neutral, or between a phase and earth. |
IEC 61000-4-30 Definition 3.1 |
|
declared input voltage, Udin |
value obtained from the
declared supply voltage by a transducer ratio |
IEC 61000-4-30 Definition 3.2 |
|
declared supply voltage |
value of a voltage different
from the nominal voltage obtained by agreement between the electricity
supplier and a consumer |
IEC 61000-4-30 Definition 3.3 |
|
dip |
See
Sag. |
|
|
Dynamic accuracy |
Accuracy
determined for a time-varying output |
IEEE 100 |
|
Dynamic range |
The
ratio, usually expressed in decibels, of the maximum to the minimum signal
input amplitude over which an amplifier can operate within some specified
range of performance. |
IEEE 100 |
|
flagged data |
for
any measurement time interval in which interruptions, sag (dip)s or swells
occur, the measurement results of all other parameters made during this time
interval are flagged |
IEC 61000-4-30 Definition 3.5 |
|
flicker |
impression of unsteadiness of
visual sensation induced by a light stimulus whose luminance or spectral
distribution fluctuates with time |
(IEV 161-08-13) IEC 61000-4-30 Definition 3.6 |
|
Frequency bins |
The
inherent frequency resolution of the discrete Fourier transform function |
|
|
fundamental
component |
component
whose frequency is the fundamental frequency |
(IEV 101-14-49 modified) IEC
61000-4-30 Definition 3.7 |
|
fundamental frequency |
frequency in the spectrum obtained from a
Fourier transform of a time function, to which all the frequencies of the
spectrum are referred NOTE
- In case of any remaining risk of ambiguity, the power supply frequency
should be referred to the polarity and speed of rotation of the synchronous
generator(s) feeding the system. |
(IEV 101-14-50 modified) IEC 61000-4-30 Definition 3.8 |
|
harmonic component |
any of the components having a harmonic
frequency NOTE Its value is normally expressed as an r.m.s.
value. For brevity, such component may be referred to simply as a harmonic |
IEC 61000-2-2, definition 3.2.4. |
|
harmonic frequency |
frequency which is an integer multiple of
the fundamental frequency NOTE - The ratio of the harmonic
frequency to the fundamental frequency is the harmonic order |
IEC 61000‑2-2, definition 3.2.3 |
|
hysteresis |
phenomenon represented by a characteristic
curve which has a branch, called ascending branch, for increasing values of
the input variable, and a different branch, called descending branch, for
decreasing values of the input variable. NOTE
– Sometimes a dead band effect can be superposed on a hysteresis phenomenon. |
(IEV 351-14-22) IEC 61000-4-30 Definition 3.11 |
|
influence
quantity |
any quantity which may affect the working
performance of a measuring equipment NOTE - this quantity is generally external to the measurement equipment |
(IEV 311-06-01 modified). IEC 61000-4-30
Definition 3.12 |
|
interharmonic
component |
component having an interharmonic frequency NOTE - Its value is normally expressed as an
r.m.s. value. For brevity, such a component may be referred to simply as an interharmonic |
IEC 61000-2-2, definition 3.2.6 |
|
interharmonic frequency |
any frequency which is not an integer
multiple of the fundamental frequency NOTE 1 By extension from harmonic order, the interharmonic
order is the ratio of an interharmonic frequency to the fundamental
frequency. This ratio is not an integer (Recommended notation m). NOTE 2 In the case where m < 1 the term subharmonic
frequency may be used. |
IEC 61000-2-2, definition 3.2.5 |
|
interruption |
reduction of the voltage at a
point in the electrical system below a threshold |
IEC 61000-4-30 Definition 3.15 |
|
interruption threshold |
voltage magnitude specified for
the purpose of detecting the start and the end of a voltage interruption |
IEC 61000-4-30 Definition 3.16 |
|
Maximum swell magnitude voltage |
The largest value of Urms(1/2)
measured
on any channel during the swell. |
IEC 61000-4-30 Definition 5.4.3.2 |
|
Mean ( |
where
N is total number of samples, xi is the ith sample |
|
|
measurement uncertainty |
maximum
expected deviation of a measured value from its actual value |
IEC 61000-4-30 Definition 3.17 |
|
Missing voltage |
The voltage waveform that would
need to be generated and summed into a sag or swell waveform to restore it to
the original (pre-fault) waveshape. |
|
|
nominal voltage, UN |
voltage by which a system is designated or
identified |
IEC 61000-4-30 Definition 3.18 |
|
overdeviation |
difference
between the measured value and the nominal value of a parameter, only when
the measured value of the parameter is greater than the nominal value |
IEC 61000-4-30 Definition 3.19 |
|
power quality |
The concept of powering
and grounding sensitive equipment in a manner that is suitable to the
operation of that equipment. NOTE—Within the industry,
alternate definitions or interpretations of power quality have been used,
reflecting different points of view.
Therefore, this definition might not be exclusive, pending development
of a broader consensus. |
Heydt, G.T. 1991. Electric power quality. West LaFayette,
Indiana: Stars in a Circle Publications. |
|
|
characteristics of the electricity at a
given point on an electrical system, evaluated against a set of reference
technical parameters. NOTE These parameters might, in some cases, relate to the compatibility between electricity supplied on a network and the loads connected to that network. |
IEC 61000-4-30 Definition 3.20 |
|
Observation Window |
Sampled
signal which occurs during a predefined period. |
IEC 61000-4-30 |
|
Precision |
The
quantity of coherence or repeatability of measurement data, customarily
expressed in terms of the standard deviation of the extended set of
measurement results from a well-defined (adequately specified) measurement
process in a state of statistical control.
The standard deviation of the conceptual population is approximated by
the standard deviation of an extended set of actual measurements. |
|
|
|
Precision
is an indication of the likelihood that a measurement will differ from the
same measurement at a different, but not correlated, time. The assessment interval specification is
also needed to assess precision values. For example, the precision could be
assessed using measurements every 3-s interval. |
|
|
Resolution |
The
smallest change in the measured or supplied quantity to which a numerical
value can be assigned without interpolation. Note.:
the resolution of most digital instruments is specified in terms of the
number of bits that the analogue to digital converter can provide. Suppliers have invented several wordings such as effective bits. |
IEC dictionary |
|
r.m.s. ( |
The
root mean square,defined by |
|
|
|
square root of the arithmetic mean of the
squares of the instantaneous values of a quantity taken over a specified time
interval and a specified bandwidth |
(IEV 101-14-16 modified). IEC 61000-4-30
Definition 3.21 |
|
r.m.s. voltage refreshed each half cycle, Urms(1/2) |
value
of the r.m.s. voltage measured over one cycle, commencing at a fundamental
zero-crossing, and refreshed each half cycle NOTE1: This technique is independent for each
channel, and will produce r.m.s. values at successive times on different
channels for polyphase systems. NOTE2: This value is used only
for voltage sag (dip), voltage swell, and interruption detection |
IEC 61000-4-30 Definition 3.22 |
|
Range of influence quantities |
range of values of a single influence
quantity |
IEC 61000-4-30 Definition 3.23 |
|
reference channel |
one
of the voltage measurement channels designated as the reference channel for
poly-phase measurements |
IEC 61000-4-30 Definition 3.24 |
|
retained voltage, Uret |
minimum value of Urms(1/2)
recorded during a voltage sag (dip) or interruption. NOTE
The retained voltage is expressed as a value in volts, or as a percentage or
per unit value of the declared input voltage. |
IEC 61000-4-30 Definition 3.25 |
|
|
|
|
|
sliding reference voltage, Usr |
voltage magnitude averaged over a specified
time interval, representing the voltage preceding a voltage sag (dip) or
swell NOTE
- The sliding reference voltage is used to determine the voltage change
during a sag (dip) or a swell |
IEC 61000-4-30 Definition 3.26 |
|
sag (dip) threshold |
voltage
magnitude specified for the purpose of detecting the start and the end of a
voltage sag. The use of the term dip
is the equivalent of sag for purposes of this document. |
IEC 61000-4-30 Definition 3.27 |
|
Sampled signal |
Signal
representing a variable which is only intermittently observed and
represented. The sequence of values of a signal taken at discrete instants. |
|
|
Sideband |
The
spectral components resulting from the modulation of a sinusoidal carrier and
lying above or below the carrier frequency.
Note:
Sideband designates a frequency band lying above or below a sinusoidal
carrier frequency and containing spectral components of significance produced
by modulation. Flicker originated from
a lamp is produced by the modulation of the power-system voltage operated
at the fundamental frequency. Thus, the fundamental frequency is the
carrier frequency and the modulation produces the sidebands. |
IEC dictionary |
|
signal |
A
measurable variable, one or more parameters of which carry information about
one or more variables which the signal represents |
|
|
swell threshold |
voltage
magnitude specified for the purpose of detecting the start and the end of a
swell |
IEC 61000-4-30 Definition 3.27 |
|
time aggregation |
combination
of several sequential values of a given parameter (each determined over
identical time intervals) to provide a value for a longer time interval Note Aggregation in this document always refers
to time aggregation. |
IEC 61000-4-30 Definition 3.28 |
|
Traceability |
Traceability
is an attribute of some measurements.
Measurements have traceability to the designated standards if an only
if scientifically rigorous evidence is produced on a continuing basis to show
that the measurement process is producing measurement results (data) for
which the total measurement uncertainty, relative to national or other
designated standards is quantified |
|
|
underdeviation |
absolute
value of the difference between the measured value and the nominal value of a
parameter, only when the value of the parameter is lower than the nominal
value |
|
|
Voltage sag (dip) |
temporary reduction of the voltage at a
point in the electrical system below a threshold NOTE - 1: Interruptions are a special case of sag
(dip). Post-processing may be used to
distinguish between sag (dip)s and interruptions. NOTE - 2; In some areas of the
world a voltage sag (dip) is referred to as sag. The two terms are considered
interchangeable, however this standard will only use the term voltage sag
(dip). |
|
|
voltage swell |
temporary
increase of the voltage at a point in the electrical system above a threshold |
|
|
voltage unbalance |
condition in a poly-phase system in which
the r.m.s. values of the line voltages (fundamental component), or the phase
angles between consecutive line voltages, are not all equal NOTE - 1: The degree of the inequality is usually
expressed as the ratios of the negative and zero sequence components to the
positive sequence component NOTE - 2: In this standard
voltage unbalance is considered in relation to three-phase systems. |
(VEI 161-08-09 modified) IEC 61000-4-30
Definition 3.31 |
2.3 Classes of measurement performance
For each parameter measured, two classes of measurement performance are
defined:
·
Class A performance
·
This class of performance is used where precise measurements are
necessary, e.g. for contractual applications, verifying compliance with
standards, resolving disputes, etc. Any measurements of a parameter carried out
with two different instruments complying with the requirements of class A, when
measuring the same signals, will produce matching results within the specified
uncertainty.
To
ensure that matching results are produced, class A performance instrument
requires a bandwidth characteristic and a sampling rate sufficient for the
specified uncertainty of each parameter.
·
Class B performance
This class
of performance may be used for statistical surveys, troubleshooting
applications, and other applications where low uncertainty is not required.
For each performance class the range of
influencing factors that shall be complied with is specified in Section 5.
Users shall select the class of measurement performance taking account of the
situation of each application case.
NOTE - 1: A measurement instrument may have different
performance classes for different parameters.
NOTE - 2: The instrument supplier shall declare
influence quantities which are not expressly given and which may degrade
performance of the instrument.
3 Organization of the measurements
3.2 Basic Blocks
The whole measurement chain
is shown in Figure 1.
An "instrument" usually includes the
whole measurement chain (see Figure 1). In this standard, the normative part
does not consider the measurement transducers including uncertainty, but the
Annex A.2 gives guidance.
3.3 Electrical values to be measured
Measurements can be performed on single-phase or
poly-phase supply systems. Depending on the context, it may be necessary to
measure voltages between phase conductors and neutral (line-to-neutral) or
between phase conductors (line-to-line) or between neutral and earth. It is not
the purpose of this standard to impose the choice of the electrical values to
be measured. Moreover, except for the measurement of voltage unbalance, which
is intrinsically poly-phase, the measurement methods specified in this document
are such that independent results can be produced on each measurement channel.
Current measurements can be performed on each
conductor of supply systems, including the neutral conductor and the protective
earth conductor.
NOTE: It is often useful to measure current simultaneously
with voltage, and to associate the current measurements in one conductor with
voltage measurements between that conductor and a reference conductor, such as
an earth conductor or a neutral conductor.
3.4 Measurement aggregation over time intervals
·
For class A
performance
A measurement time interval of magnitudes
(supply voltage, harmonics, interharmonics and unbalance) shall be over a
10-cycle time interval for 50 Hz power system or 12-cycle time interval
for 60 Hz power system.
NOTE The uncertainty of this measurement is
included in the uncertainty measurement protocol of each parameter.
Measurement time intervals are aggregated
over three different time intervals. The aggregation time intervals are:
– 3-s interval (150 cycles for 50 Hz
nominal or 180 cycles for 60 Hz nominal),
– 10-min interval,
– 2-h interval.
·
For class B
performance
The
supplier shall indicate the method, number and duration of aggregation time
intervals.
3.4.1 Measurement aggregation algorithm
Aggregations are performed using the square root
of the arithmetic mean of the squared input values.
NOTE: For flicker measurements, the aggregation
algorithm is different (see IEC 61000‑4-15).
Three categories of aggregation are necessary:
– Cycle
aggregation
The data
for the 150/180-cycle time interval shall be aggregated from fifteen
10/12-cycle time intervals.
NOTE: This time interval is not a "time
clock" interval; it is based on the frequency characteristic.
– From cycle
to time clock aggregation
The
10-minute value shall be tagged with the absolute time (e.g. 01H10.00). The
time tag is that at the end of the 10-minute aggregation. If the last 10/12 cycle value in a 10-minute
aggregation period overlaps in time with the absolute 10-minute clock boundary,
that 10/12 cycle value is included in the aggregation for this 10-minute
interval.
On
commencement of the measurement, the 10/12 cycle measurement shall be started
at the boundary of the absolute 10-minute clock, and shall be re-synchronised
at every subsequent 10-minute boundary.
Note: This technique implies that a very small amount
of data may overlap and appear in two adjacent 10-minute aggregations.
– Time clock
aggregation
The data for the
“2-h interval” shall be aggregated from twelve 10-min intervals.
3.4.2 Time clock uncertainty
The time clock uncertainty is:
·
For class A
performance
± 20 ms
for 50 Hz or ± 16,7 ms for 60 Hz.
NOTE - 1: This performance can be achieved, for
example, through a synchronization procedure applied periodically during a
measurement campaign, or through a GPS receiver, or through reception of
transmitted radio timing signals. The
recalibration rate should be at a rate necessary to maintain the required time
accuracy.
NOTE - 2: When synchronisation by an external signal
becomes unavailable, the time tagging tolerance must be better than 1 seconds
/24 hours.
NOTE - 3: This performance is necessary to ensure that
two class A instruments produce the same 10-min aggregation results when
connected to the same signal.
NOTE 4: When a threshold is crossed, it may be useful
to record the date and time.
·
For class B
performance
The
supplier shall specify the method to determine 10-min intervals.
4 Supply voltage sag (dip)s and swells
4.2 Basic measurement
The basic measurement of a voltage sag (dip) and swell shall be the Urms(1/2) on each measurement
channel.
NOTE
- 1: For class A, the cycle duration for Urms(1/2) depends on the
frequency. The frequency might be determined by the last non-flagged power
frequency measurement, or by any other method that yields the uncertainty
requirements of Section 5.
NOTE
- 2: The Urms(1/2)
value includes, by definition, harmonics, interharmonics, ripple control
signals, etc.
4.2.1 Detection and evaluation of a voltage sag (dip)
4.2.1.1
Voltage sag (dip)
detection
The sag (dip) threshold is a percentage of either Udin or the sliding
voltage reference Usr
(see 5.4.4). The user shall declare the reference voltage in use.
NOTE:
Sliding voltage reference Usr
is generally not used in LV systems. See IEC 61000-2-8 for further information
and advice.
–
On single-phase system, a voltage sag (dip) begins when
–
the Urms(1/2)
voltage falls below the sag (dip) threshold, and ends when the Urms(1/2)
voltage is equal to or above the sag (dip) threshold plus the hysteresis
voltage. This method is only resolvable to +/- ½ cycle, or,
–
When the DC equivalent voltage drops (see Section 6.9) below a threshold
and ends when the DC equivalent voltage is equal to or above the threshold plus the hysteresis voltage.
–
On polyphase system a sag (dip) begins
o
when the Urms(1/2)
voltage of one channel, at least, is below the sag (dip) threshold and
ends when the Urms(1/2)
voltage on all measured channels is equal to or above the sag (dip)
threshold plus the hysteresis voltage.
This method is only resolvable to +/- ½ cycle.
o
When the DC equivalent voltage drops below a threshold and ends when the
DC equivalent voltage is equal to or above the
threshold plus the hysteresis voltage.
–
The sag (dip) threshold and the hysteresis voltage are both set by the
user according to the use.
4.2.1.2
Voltage sag (dip)
evaluation
A voltage sag (dip) is characterized by a pair of data, either retained
voltage (uret) or depth and
duration.
–
The retained voltage is the smallest Urms(1/2) value measured on
any channel during the sag (dip).
–
The depth is the difference between the reference voltage (either Udin
or Usr) and the retained voltage. It is generally expressed in % of
the reference voltage.
–
The duration of a voltage sag (dip) is the time difference between the
beginning and the end of the voltage sag (dip).
–
Missing voltage (see Annex 6.5) can provide a different precision on the
beginning and ending on the DC equivalent voltage to what:
–
an ASD experiences for
over/undervoltage measurements.
–
Contactors respond to. [RANDY]
–
Sliding window can provide an interpretative beginning and ending on the
DC equivalent voltage for utility benchmark methods.
NOTE
- 1: The sag (dip) duration measurement can be started on one channel and
terminated on a different channel.
NOTE
- 2: Voltage sag (dip) envelopes are not necessarily rectangular. As a
consequence, for a given voltage sag (dip), the measured duration is dependent
on the selected sag (dip) threshold value. The shape of the envelope may be
assessed using several sag (dip) thresholds set within the range of voltage sag
(dip) and voltage interruption thresholds detection.
NOTE
- 3: Typically, the hysteresis is equal to 1 to 2 % of Udin.
NOTE
- 4: Sag (dip) thresholds are typically90 % of the voltage reference
NOTE
- 5: Retained voltage is often useful to end-users, and may be preferred
because it is referenced to zero volts.
In contrast, depth is often useful to electric suppliers, especially on
HV systems or in cases when a sliding reference voltage is used.
NOTE
- 6: Phase shift may occur during voltage sag (dip)s. See Section 6.4.
NOTE
- 7: When a threshold is crossed, it may be useful to record the date and time.
4.2.2 Detection and evaluation of a voltage swell
4.2.2.1
Voltage swell detection
The swell detection threshold is a percentage of either Udin. or the sliding
voltage reference Usr
(see 5.4.4). The user shall declare the reference voltage in use.
NOTE Sliding voltage reference Usr is generally not used in
LV systems. See 61000-2-8 for further information and advice.
– On single-phase system a swell
begins when the Urms(1/2) voltage is above
the swell threshold, and ends when the Urms(1/2) voltage is equal to
or below the swell threshold minus the hysteresis voltage.
–
On poly-phase system a swell begins when the Urms(1/2) voltage of one
channel, at least, is above the swell threshold and ends when the Urms(1/2) voltage on all
measured channels is equal to or below the swell threshold minus the hysteresis
voltage.
–
DC Equivalent wording supplemented by R,A,E.
The swell threshold and the hysteresis voltage are both set by the user
according to the use.
4.2.2.2
Voltage swell
evaluation
A voltage swell is characterised by a pair of data, maximum swell
voltage magnitude and duration.
– The maximum swell magnitude
voltage is the largest Urms(1/2) value measured on
any channel during the swell.
– The
duration of a voltage swell is the time difference between the beginning and
the end of the swell.
NOTE
- 1: The swell duration measurement can be started on one channel and
terminated on a different channel.
NOTE
- 2: Swell envelopes may not be rectangular. As a consequence, for a given
swell, the measured duration is dependent on the swell threshold value.
NOTE
- 3 Typically, the hysteresis is equal to 1- to 2 % of Udin.
NOTE
- 4: the swell threshold is typically
greater than 105 to 110 % of Udin
NOTE
- 5: Phase shift may also occur during voltage swells.
NOTE
- 6: When a threshold is crossed, it may be useful to record the date and time.
4.2.3 Calculation of a sliding reference voltage
If a sliding
reference is chosen for voltage sag (dip) or swell detection, this shall be
calculated using a first-order filter with a 1-min time constant. This filter
is given by:
Usr(n) = 0.9967 x Usr(n–1) + 0.0033 x U(10/12)rms
where
Usr(n)
is the present value of the sliding reference voltage,
Usr(n–1)
is the previous value of the sliding reference
voltage, and
U(10/12)rms
is the most recent 10/12-cycle r.m.s. value.
When the measurement
is started, the initial value of the sliding reference voltage is set to the
declared input voltage. The sliding reference voltage is updated every
10/12-cycles. If a 10/12-cycle value is flagged, the sliding reference voltage
is not updated and the previous value is used.
4.2.4 Measurement uncertainty
4.2.4.1
Retained voltage and
maximum swell voltage magnitude measurement uncertainty
·
For class A
performance
The
uncertainty shall be DU = ±0.2 % of Udin.
·
For class B
performance
The supplier shall specify the
uncertainty. In all cases the uncertainty DU shall be
±1.0 % of Udin.
4.2.5 Duration measurement uncertainty
·
For class A and
class B performances
The uncertainty of a sag (dip) or swell duration is
equal to the sag (dip) or swell commencement uncertainty (half a cycle) plus
the sag (dip) or swell conclusion uncertainty (half a cycle).
Range of influence quantities and implementation verification
4.1 Range of influence quantities
The
measurement of a specific characteristic can be adversely affected by the
application of a disturbing influence (influence quantity) on the electrical
input signal; e.g. the measurement of supply voltage unbalance can be adversely
affected if the voltage waveform is at the same time subject to a harmonic
disturbance.
The
result of a parameter measurement shall be within the specified uncertainty
given in this section when all other parameters are within their range of
variation, given in the Tables 5-1 and 5-2.
Table 5-1 – Range of influence quantities (of the input
signals) for class A performance
|
Influence
quantities |
Range
of variation |
|
Frequency |
42,5 Hz
– 57,5 Hz for 50 Hz systems 51 Hz
– 69 Hz for 60 Hz systems |
|
Voltage
magnitude (steady state) |
0 %
– 200 % of Udin |
|
Flicker
(Pst) |
0 –
20 |
|
Unbalance |
0 %
– 5 % |
|
Harmonics
(THD) |
Twice the values in IEC 61000‑2-4,
class 3, which are listed in Table 5-1a |
|
Interharmonics
(at any frequency) |
Twice
the values in IEC 61000‑2-4, class 3, which are only those
interharmonic frequencies below the 2nd harmonic that would result
in a flicker severity Pst = 1. |
|
Mains
signalling voltage |
0 –
9 % of Udin |
|
|
|
|
|
|
NOTE: Pst shall be
produced by periodic modulation.
|
per
61000-2-4: Table 5 |
|
|
|
|
|
|
Total
Harmonic Distortion |
10% |
|
|
|
|
|
|
|
|
|
|
|
|
per 61000-2-4: Table 3 Odd harmonics, multiples of
3 |
Class 3 |
per 61000-2-4: Table 2 Odd harmonics, non multiples
of 3 |
Class 3 |
per 61000-2-4: Table 4 Even harmonics |
Class 3 |
|
3 |
6 |
5 |
8 |
2 |
3 |
|
9 |
2.5 |
7 |
7 |
4 |
1.5 |
|
15 |
2 |
11 |
5 |
6 |
1 |
|
21 |
1.75 |
13 |
4.5 |
8 |
1 |