VOLTAGE CONTROL ISSUES IN LOW VOLTAGE NETWORKS
WITH MICROGENERATION
Rui Castro, M. E. Almeida, Célia Jesus, Pedro M. S. Carvalho and Luís A. M. Ferreira
Centre for Innovation in Electrical and Energy Engineering (Cie
3
), IST – Technical University of Lisbon, Lisbon, Portugal
Keywords: Voltage Control, Microgeneration, Transformer Tap Changer, Unbalanced Load Flow.
Abstract: In the framework of the so-called microgeneration, small photovoltaic units are being installed in the roofs
of the buildings and connected to the low-voltage distribution networks. This is posing some new challenges
to the distribution network operators. On one hand, the off-service regulation of the transformer taps must
comply with a hard twofold objective: to mitigate the undervoltages during peak load periods and to
mitigate voltage rise during peak generation periods. On the other hand, the voltage profile is almost
insensitive to microgeneration injected reactive power, which forces control to actuate on active power with
the consequent impact on energy produced and also on network security. These two aspects of the problem
are addressed in this paper with help from an illustrative test network, on which several case-studies have
been built to highlight the main voltage control problems and to test different strategies to overcome such
problems.
1 INTRODUCTION
Recently, governments are encouraging the
installation of small Photovoltaic (PV) units (usually
in the roofs of the buildings), typically sized in the
range of some kW and connected to the Low
Voltage (LV) distribution network, in the framework
of the so-called microgeneration (µG). This is a way
of indirectly reduce the net load as seen from the
electrical system, because these generation units can
produce locally part of the energy consumed by the
system.
µG consists of a combination of generation
sources, usually renewable, that interface with the
LV distribution network through fast acting power
electronics. LV networks have been originally
designed to feed loads, so the introduction of
generation sources is a quite innovative aspect that
can significantly impact the flow of power and
voltage conditions.
PVs will produce electrical energy during
daylight, a period in which the load as seen from the
distribution transformer is expected to be quite low
in domestic areas. As a consequence, the power that
flows to the loads will be reduced or even be
reversed, which may cause the bus voltages to rise.
This will require some countermeasures to be
undertaken. Traditionally, this issue is dealt with by
an appropriate reactive power control. This can be
locally performed by the inverters of the PV, which
hold power factor regulation capabilities. However,
reactive power control is very ineffective in LV
networks due to the low inductive component of the
LV lines/cables. Therefore, the alternative is to
reduce the active power injected by the PVs into the
network. To cope with this purpose, the PVs must be
able to receive commands specifying the maximum
power generation level, when the voltage is out of its
range. The control of µG induced overvoltages is to
be dealt with in the scope of this paper.
Another issue related to the penetration of µG in
the LV networks concerns the tap setpoint of the
MV/LV transformer. Usually, MV/LV transformers
do not have automatic on-load tap-changing
capabilities. Instead, a fixed tap is selected with the
transformer off service. Until now, this tap has been
chosen so that the voltage along the entire feeder is
above the lower limit at peak-load hours (off-peak
generation hours). However, with embedded µG, the
chosen tap must also guarantee that the voltage
along the feeder is under the upper limit at off-peak
load hours (peak generation hours). This twofold
objective can be hard to achieve. Furthermore, it is
expected that the transformer tap changes impact
differently on voltage profile depending on the
79
Castro R., Almeida M., Jesus C., M. S. Carvalho P. and A. M. Ferreira L..
VOLTAGE CONTROL ISSUES IN LOW VOLTAGE NETWORKS WITH MICROGENERATION.
DOI: 10.5220/0003952700790084
In Proceedings of the 1st International Conference on Smart Grids and Green IT Systems (SMARTGREENS-2012), pages 79-84
ISBN: 978-989-8565-09-9
Copyright
c
2012 SCITEPRESS (Science and Technology Publications, Lda.)
elasticity of the loads and on the existence of
connected µG. The topic related to the impact of
MV/LV transformer tap changes is also addressed in
the paper.
The paper has been organized in case studies
based on the same test network. Case-studies have
been built with the aim of illustrating voltage control
problems in LV networks with µG and the
effectiveness of the proposed solutions to those
problems.
2 NETWORK MODEL
As LV networks are close to end-consumers, load
unbalance can be significant. Most small consumers
are single-phase consumers and therefore return
neutral currents can be high.
Sometimes neutral currents are even higher than
phase currents (Chen, 2001). Neutral currents
depend on the neutral earthling system in use, which
changes from utility to utility and from country to
country (Meliopoulos, 1998).
Several neutral earthling options are available.
These are usually designated by TN, TT and IT
earthing systems. The TN basic system is commonly
used in Europe and is characterized by the
transformers' neutral being earthed and the electrical
load frames being connected to the neutral.
Usually, for TN earthing systems, the earthing
impedance of the load frames grounding is high
enough to consider that all neutral current flows
back to the transformer, i.e., that the current through
the load earthing impedances is negligible during
normal operation. In such case, the system can be
well represented by a four-wire circuit (3-phases and
neutral) instead of a five-wire one (Chen, 2001);
(Ciric, 2003).
There is a scarce knowledge of the behaviour of
the LV distribution network in presence of
concurrent unbalanced generation and loads
(Chindriş, 2007); (Carvalho, 2008); (Thomson,
2007). The multidimensional stochastic dependence
structure of the joint behaviour of the generation and
load can be very complex to model. In this paper, we
assess the behaviour of unbalanced LV networks for
fixed load/generation profiles and variable load-to-
voltage elasticity with the so called three-phase,
four-wire, unbalanced power flow (Monfared,
2006); Ciric, 2003); (Teng, 2002).
3 MITIGATION OF INDUCED
OVERVOLTAGES WITH
POWER CONTROL
A small test network is used to get insight into the
voltage control problems caused by the injection of
µG into the radial LV networks. The test network is
a 5 bus network as depicted in Figure 1.
Figure 1: One-line diagram of the test network.
An unbalanced load flow study is carried out in
the following conditions: (i) the four cables are
equal with R/X = 10; (ii) the voltage in bus 1 is
considered constant and equal to 1.05 pu; (iii) the
loads were modelled as “constant current” (elasticity
equal to 1); (iv) the operating point is unbalanced,
the load complex power being presented in Table 1
(active power negative values correspond to µG).
Table 1: Unbalanced load profile, S
RST
, for the 5 bus test
network.
3.1 Base-case
The base-case load-flow results are presented in
Figure 2.
Figure 2: Voltage at the three phases (R, S, T) and at the
neutral for the base case.
From Figure 2 one can observe that the voltage
profile is high, namely in the phases and busbars
~
1
2
3
4
5
MV/LV
~
~
Bus 2 3 4 5
S
R
(pu)
0.10+j0.05 0.10+j0.05 0.20+j0.15 ‐0.25+j0.05
S
S
(pu)
0.10+j0.05 0.00+j0.15 ‐0.20+j0.05 0.05+j0.00
S
T
(pu) 0.05+j0.05 ‐0.20+j0.05 0.05+j0.01 0.10+j0.05
1 2 3 4 5
0.95
1
1.05
1.1
1.15
1.2
phase voltages (pu)
1 2 3 4 5
0
0.01
0.02
0.03
neutral voltage (pu)
V
R
V
S
V
T
V
R
V
S
V
T
SMARTGREENS2012-1stInternationalConferenceonSmartGridsandGreenITSystems
80
where the µG is connected (V
3T
, V
4S
, V
5R
). For
instance, in busbar 4, phase S, the voltage is higher
than 1.1 pu. The unbalance is noticeable as the
neutral voltage magnitude is significant.
In order to improve the voltage profile, the
control system features of the µGs may be used,
namely its capability to regulate reactive power.
3.2 Case 1: Reactive Power Control
This case-study concerns the effects of controlling
µG#4 (connected in phase S) in order that it absorbs
reactive power with tg(φ)=0.4. Figure 3 shows the
unbalanced load flow results for case-study 1.
Figure 3: Voltage at the three phases (R, S, T) and at the
neutral for case-study 1.
We can see that the improvement is marginal: the
voltage V
4S
is now about 1.09 pu, against 1.1 pu
before this control action was undertaken. However,
voltage V
5R
, which was 1.08 pu, is now close to
1.1 pu. The increase in the unbalance of the grid is
evidenced by the neutral voltage.
As this control action has shown to be not
effective, an alternative is to disconnect the µG. This
is to be dealt with in the next section.
3.3 Case 2: On/Off Control
Case-study 2 is related to the disconnection of
µG#4. The obtained results are shown in Figure 4.
As far as busbar 4 is concerned, the consequence
is now much more effective: voltage V
4S
has
dropped to 0.96 pu. Nonetheless, other issues
emerged: voltages V
3T
and V
5R
have risen to 1.1 pu
and 1.09 pu, respectively. Globally, the network is
more unbalanced, as shown by the neutral voltage.
The next step is to disconnect the µG# 3, which
will be performed in case-study 3.
Figure 4: Voltage at the three phases (R, S, T) and at the
neutral for case-study 2.
3.4 Case 3: On/Off Cascade
For case-study 3 (disconnection of µG#3), the
obtained results are shown in Figure 5.
As would be expected, the problem associated
with busbar 3 was fixed, but the issue now is related
to busbar 5, whose voltage has increased to 1.13 pu.
It should be pointed out that the unbalance of the
network is even larger than before. In order to obtain
an acceptable voltage profile, µG#5 ought to be
disconnected. Under these conditions, it could be
shown that all busbar voltages would stay below
1.05 pu.
It has been illustrated that by disconnecting a
single µG a cascade may occur. Furthermore, it has
been shown that µG induced overvoltages are to be
mitigated by limiting the active power they can
inject in the grid, the reactive power control option
being much ineffective.
It would be desirable taking less extreme
measures to control voltage. A way of doing so is to
shed µG injection in steps instead.
Figure 5: Voltage at the three phases (R, S, T) and at the
neutral for case-study 3.
1 2 3 4 5
0.95
1
1.05
1.1
1.15
phase voltages (pu)
1 2 3 4 5
0
0.01
0.02
0.03
0.04
0.05
neutral voltage (pu)
V
R
V
S
V
T
1 2 3 4 5
0.9
0.95
1
1.05
1.1
1.15
phase voltages (pu)
1 2 3 4 5
0
0.02
0.04
0.06
0.08
neutral voltage (pu)
V
R
V
S
V
T
1 2 3 4 5
0.9
0.95
1
1.05
1.1
1.15
phase voltages (pu)
1 2 3 4 5
0
0.02
0.04
0.06
0.08
0.1
neutral voltage (pu)
V
R
V
S
V
T
V
R
V
S
V
T
V
R
V
S
V
T
V
R
V
S
V
T
VOLTAGECONTROLISSUESINLOWVOLTAGENETWORKSWITHMICROGENERATION
81
3.5 Case 4: Active Power Control
In this case-study, the control system will issue an
order of cutting off half of the active power injected
in busbar 4, phase S. The unbalanced load flow
results for this situation may be analysed in Figure 6.
Figure 6: Voltage at the three phases (R, S, T) and at the
neutral for case-study 4.
From Figure 6, one can conclude that this more
moderated action is enough to obtain an acceptable
voltage profile at the distribution network. The
voltage V
4S
is equal to 1.03 pu and both the voltages
V
3T
and V
5R
are below 1.1 pu. Under these
circumstances, no further corrective action is
required.
4 VOLTAGE CONTROL USING
MV/LV TRANSFORMERS TAP
CHANGING
To illustrate the problems of voltage control using
MV/LV transformer tap changers, a similar
approach based on case-studies will be followed.
4.1 Case 1: The Effect of Elasticity
This case-study addresses a peak load situation with
unbalanced load and no injection by the µG. The test
network is represented in Figure 7, in which
S
i
= 0.525+j0.1715 pu for i=2, 3, 4 and 5.
Figure 7: Test network for case-study A; load peak
situation.
Power flow results are synthetized in Figure 8 for
the phase voltage changed induced by increasing the
voltage set-point of the transformer. This Figure
shows the maximum (ΔV
max
) and minimum (ΔV
min
)
bus voltage variation when the tap of the MV/LV
transformer changes from 1.05 pu to 1.075 pu. This
study was carried out for two types of load elasticity:
2 (constant impedance) and 0 (constant power).
Figure 8: Maximum and minimum bus voltage variation,
when the tap of the transformer changes from 1.05 pu to
1.075 pu; load elasticity: 2 (top) and 0 (bottom); case-
study 1.
The figure shows that the maximum bus voltage
variation follows closely the variation in the
transformer tap changer (ΔV
ref
=0.025 pu). However,
the minimum bus voltage variation does not. If the
load elasticity is 2, the minimum bus voltage
variation is smaller than the variation in the
transformer reference voltage; if the load elasticity is
0, the opposite behaviour is observed.
4.2 Case 2: Elasticity Opposite Effect
This case-study addresses an off-peak load situation
with both unbalanced load and µG. The test network
is represented in Figure 9, in which the load was
reduced to half the previous value and µG injected
power was set equal to two thirds of the previous
load. It should be remarked that the generators are
absorbing reactive power.
Figure 9: Test network for case-study 2; off-peak load
situation with microgeneration.
A summary of the power flow results is depicted
in Figure 10 for this case. This Figure shows the
maximum (ΔV
max
) and minimum (ΔV
min
) bus
1 2 3 4 5
0.95
1
1.05
1.1
1.15
phase voltages (pu)
1 2 3 4 5
0
0.01
0.02
0.03
0.04
neutral voltage (pu)
V
R
V
S
V
T
1 2 3 4 5
MV
/
LV
R
S
T
5
S
4
S
3
S
2
S
1
2
3 4 5
MV
/
LV
R
S
T
5
S
2
1
4
S
2
1
3
S
2
1
2
S
2
1
~
~
(
)
3
Q,
3
P-32
()
55
Q,P32 -
V
R
V
S
V
T
SMARTGREENS2012-1stInternationalConferenceonSmartGridsandGreenITSystems
82
voltage variation, when the tap of the transformer
changes from 1.05 pu to 1.025 pu. The reduction in
the reference voltage set-point (ΔV
ref
=–0.025 pu) is
necessary because overvoltages are expected to
occur in this situation. As before, two elasticities
were considered.
Figure 10: Maximum and minimum bus voltage variation,
when the tap of the transformer changes from 1.05 pu to
1.025 pu; load elasticity: 2 (top) and 0 (bottom); case-
study 2.
From Figure 10, the following conclusions can
be undertaken:
• Regardless of the load type, the maximum bus
voltage reduction is always smaller than the
transformer reference voltage variation.
• For loads with elasticity of 2, the minimum bus
voltage variation follows closely the maximum bus
voltage variation.
• For loads with zero elasticity, the minimum bus
voltage variation is higher than the transformer
voltage variation.
The results of cases 1 and 2 allow the conclusion
that, in LV networks, changes in the transformer tap
may impact the feeder voltages in a way that is hard
to predict. The impact in minimum voltages can be
either amplified or reduced significantly depending
on the elasticity being small or large. This, together
with the need to regulate for both high voltages in
off-peak periods and low voltage in peak periods,
makes tap changing voltage regulation a difficult
approach to voltage control in LV networks.
5 CONCLUSIONS
Up to now, it is common knowledge that voltage
decreases along the feeders in LV networks, due to
the effect of the loads. However, this might not be
the case nowadays, with the increasing penetration
of small PV generators directly connected to the LV
grids. It is expected that the voltage rises in the
daylight, when the load is low and the generation is
high. The traditional voltage control method trough
proper management of reactive power flow is
ineffective, due to the high resistive characteristics
of the LV cables/lines. Therefore, active power
control is required and the disconnection of PV
microgeneration is the straightforward solution. This
paper tries to demonstrate that this drastic measure
may be avoided, if the PVs are able to receive
commands specifying the maximum power
generation level, when the voltage is out of its
acceptable operation range. In most cases, partial
generation shedding may prove effective to control
the voltage.
The issue of proper regulation of the taps of the
MV/LV transformer is also an important one. This is
hard to achieve because it must comply with a
twofold conflicting objective: on one hand, it must
mitigate the undervoltages during peak load periods
and, on the other hand, to control the overvoltages
during off-peak load periods. Furthermore, it has
been shown in the paper that transformer tap
changes effects are difficult to predict because they
depend on the load elasticity. This makes tap
changing voltage regulation a difficult approach to
voltage control in LV networks.
ACKNOWLEDGEMENTS
This work was partially supported by EDP
Distribuição via the InovGrid project.
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