SMART GRID: MONITORING OF CABLE FAULT LOCATION
K. V. Suslov, N. N. Solonina and A. S. Smirnov
Irkutsk State Technical University, 83, Lermontov street, Irkutsk, Russia
Keywords: Smart Grid, Reliability, Rogowski Coil.
Abstract: Modern viewpoint suggests that Smart Grid is the network based on “smart technologies”; it is highly
reliable, self-controlled, and capable to receive energy from any source and transform it into a final product
without man’s participation. Changes that occur in the energy sector require higher speed of receiving and
processing the data on current state of power system. At the same time increasingly stricter requirements are
imposed on accuracy and validity of measurements of circuit parameters. The paper is devoted to solving
the problem of promptly determining the coordinates of short circuit location on transmission line, which
can be done by digital processing of information about currents in transmission lines and use of Rogowski
coil as a primary transducer.
1 INTRODUCTION
Nowadays there are different ways of providing the
required reliability of power system operation.
However, despite high reliability of power
equipment and control systems there can be failures
in operation, for example short circuits in supply and
distribution networks which can be caused by
unforeseen circumstances. Reduction of time for
search of the short circuit location on lines is a direct
way of improving the reliability of power systems.
There is a great variety of methods for detecting
location of overhead and cable line faults. We will
enumerate them in brief.
The pulse method is based on measuring time
intervals between the moment of transmitting a
probe pulse of alternating current and the moment of
receiving a reflected pulse from the fault location.
To make measurements by the method of oscillation
discharge the voltage supplied to the faulted cable
conductor is gradually raised to the voltage of cable
fault. The loop method is based on measuring
resistances by the direct current bridge. The
capacitance method is suggests measuring
capacitance of a broken conductor by measuring
bridges. The acoustic method supposes creation of a
spark discharge at the fault location and listening to
sound vibrations that occur above the fault point.
There is also the induction method and others. The
main flaw of these methods from the viewpoint of
promptness is the fact that their application requires
preparatory work and a lot of time.
2 MAJOR PRINCIPLES OF THE
APPROACH
The method suggested by the authors allows one to
timely detect the place of transmission line fault on-
line. The main idea of the method lies in the fact that
knowing circuit configuration and line parameters
we can obtain an equivalent circuit for calculation of
short-circuit currents at different points of
transmission line. Depending on the required
accuracy we choose a certain interval between the
calculated points. The points calculated theoretically
are then compared with measured short- circuit
currents.
Let us first consider the simplest case where the
short-circuit current is created by one source. Figure
1 shows a scheme of determining the location of
short circuit on transmission line for the considered
case.
There are primary current transducers at the
beginning of the line in all phases. Their
instantaneous values are processed and effective
current values are calculated. At the time of short
circuit this effective value will correspond to the
initial effective value of the short-circuit current.
Based on the relationship between phase currents the
logical circuit determines the type of short circuit.
129
V. Suslov K., N. Solonina N. and S. Smirnov A..
SMART GRID: MONITORING OF CABLE FAULT LOCATION.
DOI: 10.5220/0003947401290132
In Proceedings of the 1st International Conference on Smart Grids and Green IT Systems (SMARTGREENS-2012), pages 129-132
ISBN: 978-989-8565-09-9
Copyright
c
2012 SCITEPRESS (Science and Technology Publications, Lda.)
This makes it possible to compare real short-circuit
currents with those previously calculated and thus
determine the coordinate of l , i.e. the beginning of
section on which the short circuit occurred.
Figure 1: The scheme of detecting the cable fault point. L
– cable length, l – distance from the beginning of the line
to the point of short circuit, E
G
– system EMF, Z
G
–
internal resistance of the system, Z(l)- resistance of the
line section from its beginning to the short circuit location.
Simultaneous accurate measurement of voltage
at the point of connection allows the result to be
adjusted considering the difference between the real
voltage and calculated one. If to continuously
measure currents and voltages (updating memory)
the said values can be fixed at the moment of short
circuit. This, in particular will make it possible to
determine the point of self-clearing fault. This is
important since similar short circuit can occur in the
future. The identified location should be examined
and the reason for a potential short circuit -
eliminated.
Let us consider a general case where a short-
circuit current on the line is considerably affected by
several sources.
The number of sources depends on network
configuration. Therefore, the calculations should be
made for different possible network configurations.
From calculation made for each circuit configuration
at a rated value of voltage we obtain a matrix of
current values for different types of short circuit at
specified values of l. An example of the matrix is
given in Table 1.
It is supposed that there are primary transducers
of current and voltage at the beginning of the line
and effective values of current and voltage are
continuously measured. The indicated values are
stored in the data concentrator and constantly
updated. The location of line fault is detected in two
stages: preliminary and final.
The algorithm for preliminary detection of
coordinates of the short-circuit current location is as
follows: knowing the short-circuit currents of
different phases we determine the type of short
circuit, namely: if currents of three phases are almost
equal, this is a three-phase symmetrical short circuit;
if two currents are equal and considerably exceed
the third current, this is a two-phase asymmetrical
short circuit; if current of one of the phases
considerably exceeds the currents of other phases,
this is a one-phase short circuit. Knowing the value
of voltage at point “a” at the time instant preceding
short circuit, we adjust the data of matrix, supposing
that the calculated currents are linearly related to the
voltage. Knowing the type of short circuit we find an
interval from the matrix, within which the measured
initial effective value of short-circuit current lies.
Table 1: An example of data matrix for the first stage of
fault location detection.
i
lil
i
Δ
⋅
=
m
(
)
3
i
I
kA
()
2
i
I
kA
(
)
1
i
I kA
1
ll
Δ
=
1
()
3
1
I
(
)
2
1
I
(
)
1
1
I
2
ll
Δ
2
2
=
()
3
2
I
()
2
2
I
(
)
1
2
I
… … … … …
i-1
(
)
lil
i
Δ
⋅
−
=
−
1
1
()
3
1
−i
I
()
2
1
−i
I
(
)
1
1
−i
I
i
lil
i
Δ
⋅
=
()
3
i
I
()
2
i
I
(
)
1
i
I
i+1
(
)
lil
i
Δ
⋅
+
=
+
1
1
(
)
3
1+i
I
(
)
2
1+i
I
(
)
1
1+i
I
… … … … …
n
lnl
n
Δ
⋅
=
()
3
n
I
(
)
2
n
I
(
)
1
n
I
where i – number of calculated point of a possible
short circuit on the interval Δl;
i
l – distance from the beginning of line to the
fault location; n – the total number of points to be
calculated; Δl –sampling step (in meters);
Let it be established that the short circuit is a
three-phase one. Determine an interval that meets
the following inequality:
()
(
)
(
)
()
()
3
1
*33
1 −+
<<
isc
sc
isc
III
,
(1)
where
()
(
)
3
1+isc
I ,
()
(
)
3
1−isc
I – calculated values of short-
circuit current at calculated points
()
1+i and
(
)
1
−
i ,
respectively;
(
)
*3
sc
I
– value of short-circuit current obtained
from measurement.
We suppose that
(
)()
3*3
iscsc
II ≈ and determine an
interval from
(
)
1
−
i to
(
)
1+i , i.e.
i
ll = , within
which the short circuit occurred. To define more
exactly the point of a short circuit the sampling step
is decreased on the found interval and the exact
SMARTGREENS2012-1stInternationalConferenceonSmartGridsandGreenITSystems
130
coordinates of short circuit location are determined.
For the limited number of intervals
(
)
l
ΔΔ
the
calculation Table is filled (Table 2).
And finally the short circuit point is determined:
()
() ()
()
()
3
1
*33
1 −+
<<
jsc
sc
jsc
III
(2)
Hence,
(
)
(
)
3*3
jscsc
II ≈ and the precise coordinates
of the short circuit location are determined
iji
lll
Δ
+=
, where
ij
l
Δ
is an interval from point
()
1−j
to
()
1+j
.
Table 2: An example of data matrix for the second stage of
fault location detection.
j
()
ljl
ij
ΔΔΔ
=
cm
()
3
ij
I kA
1
(
)
ll
i
Δ
Δ
Δ
=
1
(
)
3
1i
I
2
(
)
ll
i
Δ
Δ
Δ
2
2
=
(
)
3
2i
I
… … …
j-1
()
()()
ljl
ji
ΔΔΔ
1
1
−=
−
(
)
(
)
3
1
−
j
i
I
j
(
)
ljl
ij
Δ
Δ
Δ
=
(
)
3
ij
I
j+1
()
()()
ljl
ji
ΔΔΔ
1
1
+=
+
(
)
(
)
3
1
+
j
i
I
… … …
m
(
)
lml
im
Δ
Δ
Δ
=
(
)
3
im
I
where j – number of the possible short circuit
point on the subinterval of
()
lΔ
Δ
; m – total number
of points for subinterval calculation;
(
)
l
Δ
Δ
–
sampling step (in centimeters);
()
*3
sc
I – measured
value of short-circuit current;
The obtained Tables underlie formation of the
structural scheme of the considered network
fragment to determine coordinates of the short
circuit point on-line (Fig. 2) based on measurements
of currents, voltages and frequency.
Figure 2: Structural scheme of on-line determination of the
short circuit point on the transmission line.
Block 1 is intended for measuring the current
effective values of linear voltages at the connection
point of transmission line and the current network
frequency of the fundamental harmonic. These data
come from primary transducers and are adjusted
continuously. Their values obtained directly before
the short circuit are stored. Block 2 serves for
measurement of initial effective values of short-
circuit currents during the first period after the short
circuit. Currents of all three phases are measured.
Block 3 aims to determine the short circuit type:
one-, two- or three-phase. Block 4 is a logic device
to determine network configuration that is changed
by circuit breakers. Hence, the state of network
configuration at the given moment can be
determined by the state of circuit breakers.
Information on their state arrives to Block 4 through
telemechanic channels. The network configuration
can also be specified directly by dispatcher. Block 5
represents a matrix of the rated currents of
transmission line for the concrete configuration.
Block 6 is a logic device of the first stage of
determining the section, on which the short circuit
happened. Block 7 is a logic device of the second
stage of determining the short circuit point and
includes a matrix of the rated currents for the second
stage of determining the short circuit point. Block 8
precisely determines coordinates of the short circuit
point.
The method supposes a precise measurement of
currents and voltages. Current and voltage
transformers with the iron core do not provide
specified accuracy. Particularly it concerns current
transformers, since at short-circuit currents to be
measured their magnetic conductors operate almost
in saturation mode, which leads to unforeseeable
errors. It is of no consequences for relay protection,
however, it is inadmissible for solving this
measuring problem. The linear dependence can be
provided by using Rogowski coil instead of current
transformers. In essence the former is a current-to-
voltage transducer. This is convenient for further
conversion of information from the analog form into
the digital one. High accuracy of current
measurement is due to absence of the magnetic core
in it. Since there is no ferromagnetic coil in
Rogowski coil, the output signal (voltage) will
linearly depend on the input value (current).
The magnetic field strength (
h) excited by the
measured current and the measured current (i) are
known to be related by Ampere’s circuital law:
ihdl
L
=
∫
(3)
SMARTGRID:MONITORINGOFCABLEFAULTLOCATION
131
where L — integration loop that practically
coincides with the midline of the measuring (ring)
winding.
Multiplying both sides of equality (3) by S
0
μ
we
obtain:
SihSdl
L
00
μμ
=
∫
(4)
Application of the known relations
;
0
hb
μ
=
(5)
;
0
hSbS
μ
=
(6)
Ldl
L
=
∫
(7)
where b, Ф – magnetic induction and magnetic
flux through the winding, respectively,
Differentiate both sides of equation (6) and after
some transformations the following relation is
obtained
()
te
dt
di
L
S
dt
db
==
0
μ
(7)
where
()
te — instantaneous value of the emf of
a winding turn of Rogowski coil.
In general, vectors h and dl are parallel to each
other at all points of integration loop L and then
eWtE =)(
(8)
here E(t) — instantaneous value of the emf of
the whole measuring winding of Rogowski coil
containing W turns.
Assuming the initial phase of measured current
to be zero and after differentiation the following
expression is obtained
)90sin()(
0
−= tICtE
m
ωω
(9)
where
⎟
⎠
⎞
⎜
⎝
⎛
=
L
SW
C
ωμ
0
— design factor of the
transducer.
A phase shifter is used to alter the emf phase by
+90 degrees and obtain voltage
u
1
, proportional to
load current
tCIu
m
ω
sin
1
=
(10)
For this purpose E{t) is divided by
ω
and a
positive phase shift by 90° is performed.
In order to determine voltage proportional to the
measured load voltage it is necessary first to obtain
current proportional to load voltage with the help of
resistive transducer. The obtained current comes to
Rogowski coil, at whose outlet the voltage will be
proportional to load voltage
)sin(
2
ϕ
ω
+
=
tUu
m
(11)
It should be noted in addition that division of
E(t) by
ω
eliminates one more error source, i.e.
dependence of the result on feed current frequency.
Thus, as distinct from the known methods
application of information technologies and
Rogowski coil makes it possible to determine
precise coordinates of the short circuit location on-
line with the required accuracy.
3 CONCLUSIONS
1. The authors offer the method for on-line
determination of a fault point on the transmission
line. It is based on preliminary theoretical
calculation of short-circuit currents at different line
cross-sections and determination of initial effective
values of short-circuit currents. Here the use is made
of the matrices of theoretical calculations of short-
circuit currents. The measured values of short-circuit
currents are compared with the calculated ones. The
accuracy of determining coordinates of the short
circuit point can be improved at two stages:
approximate and precise.
2. Rogowski coil is suggested for use as primary
transducers to improve the accuracy of
measurements of the current values of short-circuit
currents.
ACKNOWLEDGEMENTS
This research was financially supported by the
decree No. 220, «Measures to Attract Leading
Scientists to Russian Educational Institutions»
(Grant NO. № 11.G34.31.0044.)
REFERENCES
K. V. Suslov, N. N. Solonina, A. S. Smirnov, 2011. Smart
meters for distributed filtering of high harmonics in
Smart Grid // III International Conference on Power
Engineering, Energy and Electrical Drives, Powereng
2011, Spain, Malaga
K. V. Suslov, N. N. Solonina, A. S. Smirnov, 2011. Smart
Grid: A new way of receiving primary information on
electric power system state// IEEE PES Innovative
Smart Grid Technologies Europe 2011, Manchester,
UK
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