New Forecasting-based Solutions for Optimal Energy Consumption in
Microgrids with Load Shedding
Case Study: Petroleum Platform
Mohamed Ghaieth Abidi, Moncef Ben Smida and Mohamed Khalgui
LISI Lab, INSAT Institute, University of Carthage, Carthage, Tunisia
Keywords:
Microgrid, High Availability, Forecasting, Weather Condition, Control, Load Shedding.
Abstract:
This paper presents a new control strategy for optimal energy consumption in microgrids based on forecasting
and load shedding method. In islanded mode, only local generation resources are usable. In this mode, the
availability of resources is very influenced by meteorological factors. In order to achieve a high availability of
energy, microgrid has to satisfy high requirements on intelligent power management. The main objective of
this study is to develop a control based on the forecast of production and the priority of loads to ensure high
availability of electrical power for critical loads. A mathematical model for the proposed strategy is developed.
The simulation of this model on Matlab Simulink for different cases of microgrid topology (sources and loads)
shows clearly a high improvement of degree of availability of electrical power supply distribution in microgrid.
1 INTRODUCTION
Microgrid system is a new concept that aims to inte-
grate decentralized energy sources efficiently and re-
liably. A microgrid consists mainly of distributed en-
ergy resources, energy storage devices, flexible loads
and energy controllers. A microgrid can operate in a
connected mode if is interconnected to the main grid,
or in an island mode if is disconnected from. In island
mode, the main constraints to ensure a high avail-
ability are the intermittent behaviour of distributed
generation sources and their possible unavailability
when they are required to product. To improve the
availability, several studies are interested in the use
of hybrid sources and power management strategies
based on balancing between loads demand and pro-
duction sources. In order to achieve a high availabil-
ity of energy and minimize the influence of intermit-
tent behaviour of sources, an intelligent power man-
agement based on forecasting production and loads
shedding methods should be used. The proposed con-
trol strategy in this paper is based on the using of
the forecast weather information to predict the avail-
ability of renewable sources and the ability of refu-
elling of programmable sources in an island micro-
grid. This method gives to the microgrid management
system the ability to make the right decision about
the achievement refuelling and to choose between us-
ing the energy produced to supply total loads or us-
ing the load shedding method to store the energy in
storage devices for use thereafter in order to supply
main loads. In this paper, a mathematical approach is
presented to show the different relationships between
the different components of microgrid and the influ-
ence of their yields by the meteorological factor (in-
solation and wind). This mathematical approach is
used to show the advantage of the new forecasting
based control strategy in the improvement of avail-
ability. Several simulations on matlab Simulink of
the mathematical model of the proposed strategy are
developed for different cases of microgrid topology
(sources and loads). The simulation results show a
high improvement of availability of electrical power
supply distribution in microgrid. Comparing to the
control strategy without forecasting and load shed-
ding, this new control strategy allows to increase the
availability value from 85% to 100%. This paper is
organized as follows: Section 1 presents the state of
the art of microgrid power availability. The second
Section explains the case study and the problem. Sec-
tion 3 proposes the new control solution for optimal
availability. In Section 4, we evaluate the proposed
solution. Finally, Section 5 summarizes this paper.
2 STATE OF THE ART
Nowadays, many human activities depend critically
289
Abidi M., Ben Smida M. and Khalgui M..
New Forecasting-based Solutions for Optimal Energy Consumption in Microgrids with Load Shedding - Case Study: Petroleum Platform.
DOI: 10.5220/0005244002890296
In Proceedings of the 5th International Conference on Pervasive and Embedded Computing and Communication Systems (PECCS-2015), pages
289-296
ISBN: 978-989-758-084-0
Copyright
c
2015 SCITEPRESS (Science and Technology Publications, Lda.)
on a secure supply of energy. With Growing con-
cern about the availability of primary energy, rising
electricity demand, use of renewable energy sources
such as wind and solar become an obligation (Bhoyar
and Bharatkar, 2013). The new generation of electric
networks should integrate renewable energy into the
electrical grid (Hatziargyriou, 2014). Thus, system
security, environmental protection, quality of electric-
ity, cost of supply and energy efficiency should be
considered in new ways to meet the changing needs
in a liberalized market environment. Microgrid is a
contained network of distributed generation sources
and energy storage devices that are connected to the
loads. The generation can be from renewable sources,
that reduce (or cancel) the need to conventional en-
ergy sources. The potential for improving the avail-
ability of Microgrid power supply is one of the main
motivations behind the development and deployment
of microgrids. Because of the importance of the avail-
ability of electrical energy for various applications
and the fluctuating availability of renewable energy
sources, a lot of research are interested in different
kinds of power sources hybridisation and their avail-
ability. The adequate choice of sources is the most
important step to improve availability. The hybridi-
sation can be on the type of sources (renewable or
programmable source, energy storage devices) or on
kind of the same type of source energy storage de-
vices (wind turbine and PV, fast-dynamic storage de-
vices and long-term storage devices, fuel cell, diesel
generator) or on both of them. After an adequate
choice, the sizing of these sources plays a mattering
role in the guarantee of the continuity of service (Lo-
genthiran and Raj, 2010). Many optimizing method-
ologies are proposed to calculate the optimum size of
energy source and storage system considering avail-
ability criterion (Y. Nian and Liu, 2013). Some pa-
pers explores how microgrids availability is impacted
by the different topology design choices for the power
electronic interfaces between the distributed genera-
tion (DG) sources and the rest of the microgrid. This
work focuses on the effect of DC or AC architec-
ture choice, converter design on system availability.
Power management strategy (Wang Haiyan and BiY-
ing, 2011) also have a significant impact on the avail-
ability of electrical energy, especially in the case of in-
sufficient production of energy or hardware problem.
Several research works have been interested in the im-
pact of the strategy of control on the different crite-
ria of microgrid power supply (WANG, 2013), espe-
cially the power-quality and the availability of elec-
trical produced energy (Thang, 2012). Whatever the
approaches of control (centralized/decentralized ap-
proaches) and especially in island mode, they require
Figure 1: Petroleum platform in Gulf of Hammamet in
Tunisia.
forecasting of the generation from renewable power
sources, electricity demand (and heat demand in some
cases). Prediction of the evolution of this quantity al-
lows us to face unsafe situations and optimize produc-
tion costs and power supply availability (H.X. Yang
and Burnett, 2003) (V. and K.U, 2014) . Therefore,
forecasting options may have a direct impact on the
economic viability and supply availability of micro-
grids, since they allow them to enhance their compet-
itiveness compared to centralized generation. To have
a wider degree of freedom on control strategy of elec-
trical power supply distribution in microgrid compar-
ing to the control based on forecasting (V. and K.U,
2014) and the control based on load shedding (Lee
and Huang, 2013), we propose a new optimized con-
trol strategy combining these two aspects by taking
in consideration the priority of the load supply. The
basic idea of our proposed strategy is to use the fore-
casted weather information to predict the availability
of renewable sources of refuelling of programmable
sources in an island microgrid. We aim in this paper
to make the right decision about the achievement re-
fuelling and load shedding.
3 CASE STUDY AND PROBLEM
We will describe in this section the Microgrid archi-
tecture and the climate values and we will introduce
the problem.
3.1 Microgrid Architecture
The Microgrid investigated in this paper is an abstrac-
tion of a petroleum platform (Figure 1) islanded lo-
cated on the Tunisian Coast. This Microgrid concep-
tion adopted for this case study is composed of PV
arrays, a wind turbine, a diesel generator with its fuel
tank, a storage device (batteries) and two loads (Fig-
ure 2). The Microgrid is designed as follows:
• Each renewable energy source (PV, Wind turbine)
is sized to be able to generate the electrical power
supply required by both loads and batteries in
favourable weather conditions,
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Figure 2: Microgrid.
• Diesel generator is dimensioned to be able to pro-
duce electrical energy required by the load. The
autonomy of this source is proportional to the
level of fuel in its tank and its produced energy,
• Battery is sized to be able to provide the electri-
cal power supply required by both loads with an
autonomy proportional to its charge level and the
electrical power request by loads. The battery be-
comes another load in her charging phase,
• load 1 is a critical load, it must be always con-
nected to the grid. Load 2 is a secondary load, it
can be disconnected in some cases.
The problem in this case is the intermittent nature
of all the sources of energy in this islanded microgrid.
The availability of sources is relative to the meteoro-
logical terms (Gooding, 2013). Based on sizing solu-
tions, the system - especially the elements of storage
- must be oversized; price and weight are the weak
points of this solution. We can increase the availabil-
ity by hybridisation of sources with other sources that
can operate in the bad times, such as the waves en-
ergy sources. This solution decreases the weight sup-
ported by the platform, but it is very expensive and
this type of energy is still in the process of study and
development. In this case, an adequate management
of energy can ensure or at least improve the availabil-
ity of electrical energy for the critical loads without
needs of new sources and new weight on the platform.
This strategy can minimize the aspect of intermittent
sources of energy by the use of the forecast of the me-
teorological factors and can act accordingly.
3.2 Climate values
The proposed Microgrid management systems must
be enhanced with forecasting technical functionalities
able to predict the power production of distributed
production sources in the next hours or days. To that
purpose, historical measurements database are needed
to generate the forecasting models. In Tunisia, you
can get this data from the National Institute of Mete-
orology
1
.
3.3 Problem and Discussion
In the island function mode of a microgrid, the avail-
ability of power supply is very influenced by the in-
termittent behaviour of its distributed sources. With
a view to improve this availability, the hybridisation
and the oversizing of sources represents a good tech-
nical solution, but this solution is very expensive. In
economical point of view, the solutions based on con-
trol strategy are always the cheapest. This kind of
solution is characterized by its flexibility and ability
to be adapted to the climate change. For this reason,
a microgrid must have an intelligent control strategy
based on forecasting methods that can minimize the
impact of weather conditions on the renewable and
programmable sources availability. The strategy of
control should minimize the impact of the unavail-
ability of renewable sources by increasing the avail-
ability of backup sources (programmable sources and
storage devices).
4 CONTRIBUTION
Our contribution consists in the development of the
new forecasting-based solution for optimal energy
consumption in microgrids with Load Shedding. This
contribution is based on mathematical formulation of
the electrical network structure of Tunisian offshore
petroleum platform existing in the Gulf of Hammamet
with taking into account the weather condition.
4.1 Architecture
A microgrid is composed of Photovoltaic Cells, Wind
turbine, Battery, Diesel Generator and loads. All
the sources are sized so that each of them - when is
available- is able to meet the energy demand loads.
The availability of renewable sources depends on cli-
matic factors (insolation and wind). The availability
of the battery depends on the charge level. The battery
can be charged and discharged through the microgrid.
The diesel generator is available when the tank is not
empty. The tank can be filled with refuelling in case
of good weather. There are two types of loads in the
microgrid: (i) critical load that should be supplied all
the time, (ii) and uncritical load that can be discon-
nected from network in the case of load shedding.
1
http://www.meteo.tn
NewForecasting-basedSolutionsforOptimalEnergyConsumptioninMicrogridswithLoadShedding-CaseStudy:
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4.2 Optimal Energy Consumption
In this subsection, we will describe the notation and
the problem formulation.
4.2.1 Notation
We denote in the following by:
PV Photovoltaic Generator
WT Wind Turbine
B Battery
GE Diesel Generator
P
Source
(t) Electrical power exchanged between the
source and the rest of network
P
Load1
(t) Electrical power consumed by critical load
P
Load2
(t) Electrical power consumed by uncritical load
En Insolation
V
V
Wind speed
E
charge
Battery charge level
E
clim
Sea State
N
Charge
Level of the fuel in the tank of the diesel
generator
E
clim
0
Nominal sea State
ψ(t) Electrical power produced by this source
4.2.2 Problem Formulation
In term of availability A(t) (Equation 1), all electrical
energy sources can have two states:
• 1: available energy producer.
• 0: unavailable energy producer.
In its charging phase, the battery acts as a load that
may consume excess production. The battery can
have a third state:
• -1: load state of battery.
A
PV
(t) = 1; 0
A
W T
(t) = 1; 0
A
B
(t) = 1; 0;−1
A
GE
(t) = 1; 0
(1)
Only available sources can be connected to the
grid. The state of penetration of sources C(t) to the
network is defined by equation(2):
C
PV
(t) = d
En
En
0
e − 1
C
W T
(t) = (d
V
V
V
V
0
e − 1).A
PV
(t)
C
B
(t) = (d
E
Charge
E
Charge
0
e − 1).A
W T
(t).A
PV
(t)
C
GE
(t) = (d
N
Charge
N
Charge
0
e − 1).A
B
(t).A
W T
(t).A
PV
(t)
(2)
Where:
En
0
(t), V
V
0
(t), N
charge
0
(t) and E
clim
0
(t) are the nominal
values from which the sources are capable of produc-
ing energy.
The electrical power supplied by different sources to
the microgrid is equal to:
P
PV
(t) = C
PV
(t).ψ
PV
(t)
P
W T
(t) = C
W T
(t).ψ
W T
(t)
P
B
(t) = C
B
(t).ψ
B
(t)
P
GE
(t) = C
GE
(t).ψ
GE
(t)
(3)
The power produced in the microgrid may not be
sufficient to satisfy the totality of power demand for
all the time. For this reason, we should be allocated a
specified priority for each load. In this study, we have
two levels of priority:
• Load 1: critical load, it must be supplied most of
the time,
• Load 2: uncritical load. It can be disconnected in
the load shedding phase (C
Load2
= 0).
To ensure the availability of power supply, the pro-
duced power must check the following inequation:
P
PV
(t) +P
W T
(t)) +P
B
(t)
+P
GE
(t) ≥ P
Load1
(t) +P
Load2
(t).C
Load2
(4)
In case of basic load shedding (without forecast-
ing), the load shedding method takes into considera-
tion only the real-time information about production
and consumption.
C
Load2
(t) = f (P
PV
(t), P
W T
(t),
E
charge
, N
charge
, P
Load1
, P
Load2
)
(5)
In the case of a load shedding based on the
forecasting, the uncritical load can be disconnected.
C
Load2
can be re-written as:
C
Load2
(t) = β
GE
(t).β
B
(t)
(6)
With
β
GE
(t) = (d
∑
n
i=1
.E
Clim
(i)
n.E
Clim
0
e − 1).(d
∑
n
i=1
.N
R
(i)
n.N
R
0
e − 1)
β
B
(t) = (d
∑
n
i=1
.E
n
(i)
n.E
n
0
e − 1).(d
∑
n
i=1
.V
V
(i)
n.V
V
0
e − 1)
.(d
∑
n
i=1
.N
Charge
(i)
n.N
Charge
0
e − 1)
(7)
β
GE
(t) and β
B
(t) are predictive probabilistic in-
dex about the state of the diesel generator and battery
availability in the future. These two indexes will be
used in order to optimize the load shedding and the
refuelling system decision.
5 EVALUATION
In this section, we will deal with the power sys-
tem model as well as the simulation result of the
petroleum platform.
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5.1 Power System Modelling
We present in this subsection the photovoltaic gen-
erator, the wind turbine, the diesel generator and the
battery.
5.1.1 Photovoltaic Generator
The behaviour of photovoltaic generator (PVG) can
be presented by the following equation:
ψ
PV
(t) = η
PV G
.A
PV G
.G
ir
(8)
With:
• A
PV G
(m
2
) is the PVG surface,
• η
PV G
is the PVG conversion efficiency given by:
η
PV G
= η
r
[1-β.(Tc-Tcref)]
5.1.2 Wind Turbine
As seen in equation(9), the energy of wind turbine
.ψ
W T
and mechanical output power of wind turbine
P
m
.
ψ
W T
(V ) =
P
n
.
V −V
dem
V
n
−V
dem
, V
dem
≤ V ≤ V
n
P
n
, V
n
≤ V ≤ V
max
0, Otherwise
(9)
P
m
(t) =
1
2
.C
p
(λ, β).ρ.AV
3
(10)
With:
• ρ: Air density (Kg/m
3
),
• A: Turbine swept area (m
3
),
• V: Wind speed (m/s), V
n
: Nominal wind speed,
V
Max
: Maximal wind speed, V
dem
: Startup Wind
speed,
• C
p
(λ, β): Performance coefficient of the turbine,
• λ: Tip speed ratio of the rotor blade tip speed to
wind speed,
• β: Blade pitch angle (deg).
5.1.3 Diesel Generator
The used model is a very simple. If its tank is not
empty, the diesel generator is a generator able to pro-
vide an electrical power P
gen
. After each unit of time
T of operation of generator, the fuel level decreases
by a quantity proportional to T and P
gen
.
5.1.4 Battery
There are many models to charge and discharge the
batteries. For the problems of sizing, it is enough to
use models that feel the State Of Charge (SOC) of the
battery in a simple manner.
5.2 Simulation Result
In this subsection, a number of simulation results that
highlight the influence of: (i) the strategy of com-
mand and (ii) the oversizing of backup sources on the
availability of electrical energy are presented and dis-
cussed. We will focus mainly on calculating the avail-
ability of energy: (i) at the level of critical loads, (ii)
at the level of the entire system. We will focus also on
the evolution of the charge level of the battery and the
fuel level in the tank of diesel generator. The instanta-
neous availability may have only two values, 1 in the
case of availability and 0 in the opposite case. The
average Availability A
A
(t) is the mean value of the
instantaneous availability between time=0 and time=t
(Taylor and Ranganathan, 2013).
A
A
(t) =
1
t
Z
t
0
A(x)dx (11)
The rate of load shedding is also an important index.
It gives us the idea about the availability of electrical
energy at the level of uncritical load and also at the
entire system.
5.2.1 Case 1: Without Forecasting and Load
Shedding
This case does not address the paper’s contribution. It
deals with a simulation without forecasting and load
shedding. Two types of load are considered: both
powered or both unpowered. Note that the refuelling
occurs only in the good weather if the tank is empty.
Table 1 shows the power supply availability index for:
(i) critical loads, (ii) entire system and (iii) the load
shedding rate for uncritical loads. Since there is no
Table 1: Availability values.
Power supply availability for the main loads 0.8517
Power supply availability for all the system 0.8517
Load shedding rate 0%
load shedding, so the power supply availability for
the main loads and the power supply availability for
all the system are equal. The calculation of availabil-
ity at the level of charges has given an availability
rate equals to 85.17 %. That it may be considered
as a mediocre value. Figure 3 presents the evaluation
of the instantaneous and average power availability at
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Figure 3: Instantaneous and average availability.
Figure 4: State of penetration of sources.
Figure 5: State of charge of the battery.
the level of critical load. Figure 4 shows the state of
penetration of sources (to the microgrid) which pro-
vide energy for consumers (Equation 2).
Note that: at each moment, only one source can be
penetrated to the network. We can also see the evo-
lution of the state of charge in the battery on Figure
5.
Figure 6 gives us information about the possibil-
ity of refuelling, the act of refuelling and the evolu-
tion of level of fuel in the tank of the diesel generator.
According to this figure, we have three times of refu-
elling.
5.2.2 Case 2: Without Forecasting and with
Load Shedding
This case is interested in a simulation that we did
without forecasting but with load shedding, if the sys-
tem is powered by the non-renewable energy sources,
there is automatically a load shedding. Comparing
with the previous value of simulation without load
shedding, we note that the power supply availability
rate for critical loads increases more than 9% but the
power supply availability rate for the entire system is
decreased by 7% (Table 2). Using the strategy of load
Figure 6: Good weather, refuelling and fuel level.
Figure 7: Instantaneous and average availability.
Figure 8: Good weather, refuelling and fuel level.
Table 2: Availability values.
Power supply availability for the main loads 0.9433
Power supply availability for all the system 0.7883
Load shedding rate 36.67%
shedding, we note that the supply system becomes to-
tally unavailable only once (Figure 7). The gain that
we obtain in Case 2 comparing to Case 1 is the im-
provement of power availability at the level of critical
loads. The reader can observe this improvement by
comparing Figure 7 to Figure 3. Table 2 shows that
the application of load shedding without forecasting
desceases the power supply availability of the system
from 0.85 to 0.78.
Despite that the availability rate of the power supply
for critical loads increases, we note that the number of
refuelling act decreases. This presents an economic
gain in term of fuel and its transport (Figure 8).
Figure 9 shows the influence of load shedding on
the rate of the connected loads.
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Figure 9: Load(pu).
Figure 10: Instantaneous and average availability.
5.2.3 Case 3: With Load Shedding and
Forecasting Only for Refuelling
Case 3 is interesting in the paper’s contribution that
deals with the prediction of the future weather con-
ditions to manage the current energy consumption to
optimize the refuelling process. Using the same pre-
vious strategy of load shedding, we can optimize the
values of availability (Figure 10), if we improve the
refuelling decision system taking into consideration
the present state of tank and the provisional state-
ments of all the sources of microgrid. This fore-
cast helps the system to take the right decision of re-
fuelling: Figure 11 shows three times of refuelling
which improve the availability of the diesel generator.
Thanks to this new solution of Case 3, the power sup-
ply availability is increased from 0.94 to 0.98 (com-
pared to Case 2) thanks to the proposed Equation 7.
Table 3: Availability values.
Power supply availability for the main loads 0.9847
Power supply availability for all the system 0.809
Load shedding rate 36.67%
5.2.4 Case 4: With Forecasting and Load
Shedding
In this case, we present the paper’s contribution that
deals with the forecasting and load shedding. Table 4
and Figure 12 show a full availability of power supply
thanks to the proposed forecasting solution with load
shedding. Figure 13 shows the state of penetration
of sources and Figure 14 shows the state of charge
of the battery. Figure 15 shows the influence of the
load shedding on the rate of the connected loads. The
reader can observe the gain that we get by applying
Figure 11: Good weather, refuelling and fuel level.
Figure 12: Instantaneous and average availability.
Figure 13: State of penetration of sources.
Figure 14: State of charge of the battery.
Figure 15: Load(pu).
the forecasting with load shedding. Figure 16 gives
us information on the possibility of refuelling, the act
of refuelling and the evolution of the level of the fuel
in the tank of the diesel generator. In Case 4 compared
to Case 3, the power supply availability is increased
from 0.98 to 1 thanks to the proposed Equation 6 and
7.
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Figure 16: Good weather, refuelling and fuel level.
Table 4: Availability values.
Power supply availability for the main loads 1
Power supply availability for all the system 0.809
Load shedding rate 38.12%
5.2.5 Result
According to the results obtained, it can be seen that:
• The type of hybridisation affects the availability.
But when we choose the sources, the reconfigura-
tion is costly and takes time,
• Note that the load shedding is a very important
strategy to increase the availability of electric
power in the priority loads, but it decreases the
rate at secondary loads and the system as a whole,
• Load shedding may be based on real-time infor-
mation or forecasts or of course both. The right
choice of this command and forecasting methods
provide a very high availability level of critical de-
vices, which can reach 100%.
6 CONCLUSION
In order to ensure a high availability in the is-
landed and autonomous microgrid, we propose a new
forecasting-based solution for optimal energy man-
agement. The major problem of this solution is the
probabilistic aspect of the forecasting data on which
the strategy is based on to make its decision. The load
shedding increase the availability in the level of crit-
ical loads; but in return, this method decreases the
availability in the level of uncritical loads. Despite
their problems, this strategy provides good results in
a case study. Predictive control strategy can help the
microgrid to improve the power supply availability for
its user by proactive control. Comparing with existing
solutions, our new solution presents several econom-
ical and technical benefits and it can be implemented
easily. The implementation of this proposed solution
and its experimental result will be published nearly.
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