Comprehensive Management Strategy for Plug-in Hybrid Electric
Vehicles using National Smart Metering Program in Iran
(Called FAHAM)
Masoud Honarmand, Nader Salek Gilani and Hadi Modaghegh
Iran Energy Efficiency Organization (IEEO), Tehran, Iran
Keywords: Billing Solutions, Charging Management, Plug-in Hybrid Electric Vehicles, Smart Metering.
Abstract: Plug-in hybrid electric vehicles charging management as well as billing solutions may be the most important
challenges in the coming years. In this paper, a comprehensive management strategy (CMS) for plug-in
hybrid electric vehicles (PHEV) using national smart metering program in Iran (called FAHAM) is
proposed. The proposed strategy considers PHEVs charging management and billing solutions as well. An
optimization method is applied in order to shift PHEVs’ charging load and maximize load factor.
1 INTRODUCTION
Although the widespread implementation of plug-in
hybrid electric vehicles (PHEV) may introduce a
solution to the world fossil fuel shortage as well as
the air pollution crisis, the anticipation of connection
of PHEVs into the power network may bring up
many technical drawbacks that need to be addressed
properly. In the near future, a huge number of
PHEVs will add a large-scale energy demand to
power systems. An emerging issue is that a large
number of EVs simultaneously will be connected to
the grid that may put at risk the overall power
system quality and stability (Sortomme & El-
Sharkawi, 2012; Sousa et al., 2012; Pillai & Bak-
Jensen, 2011).
The intelligent scheduling and control of PHEVs
as loads or power sources have great potential for
evolving a sustainable integrated electricity and
transportation infrastructure (Honarmand et al.,
2014; Honarmand et al., 2014; Honarmand et al.,
2015; Brahman et al., 2015). Large numbers of EVs
have the potential to put at risk the stability of the
power network. The charging demand of PHEVs
needs to be managed very carefully in order to avoid
interruption when several thousand of them are
introduced into the system over a short period of
time.
In this paper, a comprehensive management
strategy (CMS) for PHEVs using national smart
metering program in Iran (called FAHAM) is
proposed in order to consider PHEVs charging
management and billing solutions as well. The
proposed strategy is capable of controlling charging
procedure of PHEVs.
The rest of this paper is organized as follows:
National smart metering project in Iran is presented
in Section II. The comprehensive management
strategy for PHEVs is stated in Section III. The
problem formulation for maximizing the load factor
is presented in Section IV. Simulation data and
results are presented and discussed in Section V.
Finally, the conclusion is given in Section VI.
2 NATIONAL SMART
METERING PROGRAM IN
IRAN (CALLED FAHAM)
Deploying an Advanced Metering Infrastructure
(AMI) is an essential early step to grid
modernization. AMI is not a single technology but it
is an integration of many technologies such as smart
meter, communication network and management
system that provides an intelligent connection
between consumers and system operators (Jadid et
al., 2013; Modaghegh & Zakariazadeh, 2013). AMI
gives system operator and consumers information
they need to make smart decisions, and also the
ability to execute those decisions that they do not
currently able to do.
252
Honarmand, M., Gilani, N. and Modaghegh, H.
Comprehensive Management Strategy for Plug-in Hybrid Electric Vehicles using National Smart Metering Program in Iran (Called FAHAM).
In Proceedings of the 5th International Conference on Smart Cities and Green ICT Systems (SMARTGREENS 2016), pages 252-256
ISBN: 978-989-758-184-7
Copyright
c
2016 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
Figure 1: The communication architecture of FAHAM project (Jadid et al., 2013).
In Iran, like many other developed countries, Smart
Grid implementation is regarded as a unique way for
encountering many serious environmental and
economic challenges. FAHAM is the National Smart
Metering Program in Iran. The functional, technical,
security, economic, and general requirements of this
project is published as a document after a long-time
workgroup of various stakeholders including
representative of grid operators, meter manufactures,
communication providers, business layer software
providers, domestic and international consultants.
Iran Energy Efficiency Organization (IEEO) is
responsible for implementation and deployment of
FAHAM. The IEEO follows promoting energy
efficiency and load management, improve system
reliability, and reduce operational costs by
implementing national smart metering project.
The simple structure of communication system in
FAHAM project is shown in Fig. 1 which consists
of:
Smart meters: These may be single phase or
three phase smart meters. Electricity meter
provides the various information for
customers such as amount of consumption
(kWh, KVarh), consumption parameters
(voltage and current), equipment status and
last information of water and gas meters.
Communication interface: Power Line
communication (PLC) and General packet
radio service (GPRS) are two communication
interface that connect two different part of
FAHAM subsystem together. Data
concentrators installed in 20kV/400V
transformer to manage all smart meters
“measured data” from such installations. Data
concentrators integrate PLC communications
that exchange information with smart meters
to communicate with central meter data
management systems.
Central Access Systems (CAS): CAS is
responsible for the management of all
information and data related to smart
metering, as well as the configuration, control
and operation of all system components. The
CAS in order to manage the FAHAM network
shall have 2 following parts: a) AMI Head
End (AHE) that has the responsibility to
manage the configuration, WAN and LAN
network management system, managing the
network equipment, Registration of equipment
and Operation & Maintenance of filed
equipment in the network. b) MDM/R that
manages and archives the acquired data from
the AHE.
Legacy Systems: These are the existing
commercial or technical systems that manage
the business processes of the utility.
3 COMPREHENSIVE
MANAGEMENT STRATEGY
FOR PHEVS
As the number of PHEVs increases, charging points
in both parking structures and private garages will
become more prevalent. These charging points will
be responsible for meeting the requirements of the
distribution grid and PHEV owners. These charging
points should perform many functions such as
Comprehensive Management Strategy for Plug-in Hybrid Electric Vehicles using National Smart Metering Program in Iran (Called FAHAM)
253
supporting the RFID cards, metering and
communication.
Figure 2: Separate billing using CMS.
The proposed CMS supports all possible
charging forms such as charging in homes, offices,
commercial buildings, charging stations, etc. To
achieve this goal, using RFID chargers has been
taken into account. In this strategy, each PHEV
takes smart energy RFID card. These cards cover
both aspects of energy sources which are used by
PHEVs, gasoline and electricity.
RFID tags inside the smart energy cards and
chargers equipped with RFID readers together with
middleware and a charging controller to authorize,
assign, and enable charging is required.
In order to simplify the charging authorization
process and make it more convenient for users, an
authentication system based on an RFID is
proposed. The layered architecture for managing a
variety of automatic identification hardware,
communicates directly with a network coordinator
and charging control server.
The other important capability of the CMS is to
separate charging bill and the general bill. In this
strategy, the PHEV owner can charge his/her PHEV
by plugging it into every possible charging facility
provided in the electrical grid and still has a
separated bill. As an example assume that PHEV
“A” which belongs to home “B”, is charging in
official building “C”. The RFID charger located at
“C” reads the PHEV’s ID number and sends it along
with the consumed energy and the charger’s ID
number to the data management center at the end of
the charging procedure. By subtracting the
consumed energy from the meter reading of the
main meter located in “C” and adding it to the
charging bill of “A”, the separated bills will be
obtained, and at the specified periods of time two
separated bills will be sent for “B”.
4 PROBLEM FORMULATION
An optimization is applied in order to shift PHEVs’
charging load for achieving the following objective
function which is maximizing load factor.
24
11
24
N
ti,t
LCh,PHEV
ti
PP
OBJ / MD
==
é
ù
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æö
÷
ç
÷
ê
ú
ç
÷
÷
ç+
ç
÷
÷
ê
ú
ç
ç
÷÷
ç
ç
èø
÷
ê
ú
ç
÷
=
ç
÷
ê
ú
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ê
ú
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ç
÷
ê
ú
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÷
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÷
ê
ú
èø
ë
û
åå
(1)
where
t
L
P
is the basic load of the feeder,
i,t
Ch ,PHEV
P
is the charging load of the i th charger,
and
M
D is the maximum demand of the feeder.
The maximization of the objective function is
subjected to the following constraints:
PHEV’s charger constraint:
i,t i
Ch ,PHEV Ch ,max
P P ; t£"
(2)
where
i
Ch ,max
P is the maximum charging power
of the
i th charger. This constraint determines the
maximum charging rate that the charger can provide.
SOC limits:
ii,ti
min max
SOC SOC SOC ; t££ "
(3)
where
i
max
SOC
and
i
min
SOC
are the maximum
and minimum SOC of the
i th PHEV, respectively.
This constraint allows the SOC to vary between
predefined minimum and maximum SOC.
Charging rate limits:
i,t i
max
SOC SOC ; tDD£"
(4)
where
i
max
SOCD
is the maximum allowable rate
for charging of the
i th PHEV. The charging rate of
battery are limited by this constraint.
Battery charging constraint:
1i,t i,t i,t
Ch,PHEV G2V
P
tRBC Cap ; thD
-
´´£ ´ "
(5)
SMARTGREENS 2016 - 5th International Conference on Smart Cities and Green ICT Systems
254
where
G2V
h
is the PHEV’s battery charging
efficiency,
1i,t
RBC
-
is the remaining battery
capacity, and
i,t
Cap
is the battery capacity. This
constraint limits the charging power of each PHEV
based on the remaining battery capacity in each
period of time.
The proposed model is solved using mixed
integer linear programming (MILP) solver CPLEX
under GAMS on a Pentium IV, 2.6 GHz processor
with 4 GB of RAM.
5 SIMULATION AND RESULTS
The Arrival and departure times of PHEVs are
assumed as random variables. A commercial feeder
is considered for this study and the PHEVs’
penetration is considered 30 percent. In this paper,
the distribution system operator manages the
charging procedure of each PHEV considering its
arrival time, approximate duration of presence in the
parking lot, and open market pricing signal. After
that the main controller uses the processed data to
optimally schedule the charging procedure of
PHEVs.
There are several types of electric vehicles in the
market with various battery capacities from 8 kWh
to 48 kWh (Pieltain Fernandez et al., 2011). In this
paper, all electric vehicles supposed to be Chevy
Volt which it is an average electric vehicle with 16.5
kWh battery capacity.
The initial SOC of each EV is considered as a
continuous uniform random number between 0.1 and
0.7. Table 1 provides the hourly electricity price of
the open market. Fig. 3 depicts the basic load of a
typical commercial feeder.
In order to analyze the robustness of the CMS,
the problem is addressed in two scenarios:
Scenario 1: There is no control on the charging
procedure of the PHEVs.
Scenario 2: The distribution system operator
manages the charging procedure of PHEVs in
order to maximize the load factor and flatten
the load profile of the feeder.
Fig. 4 shows the basic load profile of a typical
commercial feeder together with PHEVs charging
demand in scenario 1. It is obvious that the
uncontrolled charging demand of PHEVs can cause
difficult situations for distribution feeders by
overloading the feeders.
Fig. 5 shows the basic load profile of a typical
commercial feeder together with PHEVs charging
demand in scenario 2. As illustrated, by applying
Table 1: The hourly electricity price in the open market.
Hour Price Hour Price
1
0.033
13
0.215
2
0.027
14
0.572
3
0.020
15
0.286
4
0.017
16
0.279
5
0.017
17
0.086
6
0.029
18
0.059
7
0.033
19
0.050
8
0.054
20
0.061
9
0.215
21
0.181
10
0.572
22
0.077
11
0.572
23
0.043
12
0.572
24
0.037
0
500
1000
1500
2000
1357911131517192123
Power (kW)
Time(Hour)
BasicLoadProfile
Figure 3: The basic load profile of a typical commercial
feeder.
500
0
500
1000
1500
2000
2500
1 3 5 7 9 11 13 15 17 19 21 23
P
ower
(kW)
Time(Hour)
BasicLoadProfil e FinalLoadProfile ChargingDemand
Figure 4: The basic load profile of a typical commercial
feeder together with the PHEVs charging demand in
scenario 1.
500
0
500
1000
1500
2000
2500
1 3 5 7 9 11131517192123
Power (kW)
Time(H our)
BasicLoad Pro fil e FinalLoad Profile ChargingDeman d
Figure 5: The basic load profile of a typical commercial
feeder together with the PHEVs charging demand in
scenario 2.
Comprehensive Management Strategy for Plug-in Hybrid Electric Vehicles using National Smart Metering Program in Iran (Called FAHAM)
255
controlled charging through FAHAM infrastructure
and CMS strategy, the load profile of the feeder is
flattened.
The Table 2 shows the load factor of the feeder
in basic load, scenario 1, and scenario 2.
Using controlled charging leads to higher load
factor, and this can be considered as a big
opportunity of FAHAM infrastructure for the system
operator to achieve a system with much more
efficiency.
Table 2: Load Factor.
Basic
Load
Scenario
1
Scenario
2
Load Factor
0.785 0.703 0.859
6 CONCLUSIONS
The integration of PHEVs in the power networks
makes new challenges; accordingly, there is a
growing necessity to address the implications of this
technology on the power network. In this paper, a
comprehensive management strategy based on
national smart metering program in Iran is proposed.
The proposed strategy helps the system operator to
enhance the overall system efficiency. The results
showed that the charging was carried out in the
hours with lower loading, while in the hours with
higher loading, the charging demand was curtailed.
Simulation results evidenced that the use of
FAHAM infrastructure for managing of the charging
of PHEVs has eliminated the risk of an electricity
demand growth during the peak load of the network.
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