Electromagnetic Modeling of the Propagation Characteristics of Satellite Communications Through Composite Precipitation Layers


Science and Technology, 7 (2002) 91-99  
© 2002 Sultan Qaboos University 
 

Assessment of The Electrical Systems 
Interconnection in The Arab World  

M.H. Abderrazzaq  

Hijjawi Faculty for Engineering Technology, Yarmouk University, Irbid 21110, Jordan,  
Email: abder@maktoob.com.  

 تقيم ترابط نظم القوى الكهربائية في العالم العربي  

 مد عبدالرزاقمح

إن . أحدهما إقتصادي واألخر تقني   :إن اإلتجاه العالمي لربط أنظمة الكهرباء بعضها ببعض يتميز بإن له بعـد ان                :  خالصة
أنظمة الكهرباء في العالم العربي ليست مؤهـلة فقط للربط فيما بينها بل هي في امس الحاجة لتكوين شبكة واحدة تجمعها في                      

لقد تم، من خالل هذا العمل، استعراض مشاريع الربط الكهربائي، القائمة والمستقبلية، في العالم العربي               . نظام كهربائي موحد    
كما تم مناقشة تطور مراحل مشروع الربط السداسي ،بما فيه الربط           . من حيث قدراتها ووضعها وكذلك الظروف المتعلقة بها         

تم إلقاء الضوء على اهم " وأخيرا.  م1998والذي تم انجازه في نهاية عام الكهربائي االردني المصري من خالل الكيبل البحري   
 . واجهت مشروع الربط الكهربائي في مراحله األولى أو التي يتوقع أن تواجهه في مراحله المستقبلية  الصعوبات الفنية التي إما

 
ABSTRACT: The international trend of interconnecting electric power systems has two dimensions; 
economical and technical. Electric power systems in the Arab World are not only eligible, but in 
need for having a unified power grid. The potentials, status and conditions of the existing and future 
interconnections in this region are overviewed. The development of the six countries interconnection 
project, including the completed phase of Jordan-Egypt submarine link, is discussed in details. 
Finally, the main technical problems, which either faced the first stages of the project or expected to 
face the interconnected systems in the subsequent stages, are highlighted.   
 
KEYWORDS: Energy, Interconnection, Grid, Submarine Cable, Overhead lines. 

1.  Introduction 

E lectricity is the most flexible form of energy and it is considered one of the most significant indicators of economic growth. The demand for electrical energy is growing at a fast rate 
worldwide. However, the available resources are limited and not uniformly distributed among the 
countries. Therefore, it is necessary to manage these resources and utilize them in optimal form. 
The transmission of energy among the countries is achieved either in the form of crude fuel or as 
electrical energy. The later form of energy transmission is found more flexible, economical and 
reliable for adjacent countries, planning to promote their future cooperation in the energy sector. 

The interconnection of electric power has been a well-established practice since the 
development of the three phase AC systems (Ibrahim, 1996). Therefore, many existing 
interconnections with transmission lines running across territories, having different 
climatic conditions and topographies, were employed a long time ago. The factors behind 
these interconnections, and which encouraged the countries to get involve in these 
projects, were mainly of economical and technical nature (Sackey and Zakhary, 1996). 
The interconnection allows for sharing the reserve margins between electrical systems. 
Consequently countries will not need to build as many generating stations on their 
territories. Moreover, the exchange of electrical energy in normal and emergency 
circumstances should improve the economies of national power systems and provide a 

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M.H. ABDERRAZZAQ 

high degree of security to all sides of the interconnection. Generally, to benefit from all 
these advantages, the interconnection project requires thorough investigation followed by 
a solid preparation and strong commitment.  

The electric systems in the Arab World are in need of interconnections more than 
other systems in the region. There are several Arab countries whose national networks 
are not yet interconnected. Unfortunately, the plans proposed to set up unified power 
grids in these countries many years ago progressed rather slowly. Despite this difficulty, 
the power systems in the Arab countries are more eligible for interconnection than other 
systems in the world due to the availability of all energy sources in the area and the ease 
of transmitting this energy between neighboring countries. The positive aspects of 
interconnection, and its impact on improving the integration capability of the economic 
systems and reinforcing the national grids, were clear to all decision makers in the Arab 
countries three decades ago. However, a long time has elapsed before started thinking 
seriously about the vitality of the interconnection project and only a few of them are now 
actually working in this direction.  

In this work, the current interconnection projects in the Arab world are overviewed 
and evaluated. The technical difficulties of the new interconnections are discussed based 
on the most recent available data. The paper will highlight the various aspects of the 
project linking Egypt, Jordan, Syria, Lebanon, Iraq and Turkey, which is currently called 
(EIJLST) interconnection project. 

2. Overview of the Interconnections Among the Arab Countries  

Some electric systems in the adjacent Arab countries have been connected for years. 
However, these links were limited in capacity and the amount of the exchangeable 
energy was rather small and fluctuated from year to year (AMRO, 1997). This fluctuation 
was mainly attributed to political reasons and only in some cases to the technical 
difficulties.  

Moreover, a serious look at these links shows that they have been established in 
response to some imminent and emergency cases, which made them not adequately 
planned and not designed as permanent interconnections. As a result, these weak links 
were incapable of carrying high quantities of electrical energy from one system to 
another. This in fact leads to the real need for new reliable interconnections linking all 
countries in the region. Figures 1 and 2 show the maps of Arab countries, with some 
links connecting neighboring systems or planned to connect them.  

In fact, the international trend in this direction has greatly encouraged the planners 
and designers of electric systems in the Arab countries to go faster in the way of 
establishing a unified Arab network. One of the largest regional projects in this direction 
was the six countries interconnection project, EIJLST. These countries are characterized 
by their location and by having vital terminal points with networks in Europe, Asia and 
Africa. 

In fact, the first and second parts of the interconnection have already been completed 
with the electric power networks of Egypt, Jordan and Syria being linked. The Egypt-
Jordan link via the Red Sea was the real technical and economical challenge to the main 
EIJLST interconnection project. Despite the technical difficulties, which faced this 
project in the initial stage and which were mainly related to the 400kV oil-filled 
submarine cable, the link is currently serving the interconnection effectively. Figure 3 
illustrates the main constituents of this cable, which was of special design to withstand 
the extreme mechanical load, caused by the topographical and unusual depths of the Red 
Sea, (Abderrazzaq and Alzahawi, 1996). Figure 4 shows a simplified diagram of the 
Jordan-Egypt link. On the Egyptian side, it was necessary to connect Taba substation 
with Suez power station via a 400kV, 500MW, 330km transmission line, whereas in the 

 92



ASSESSMENT OF THE ELECTRIC SYSTEMS INTERCONNECTION 

Jordanian side it was necessary to establish a new 400kV substation and to reinforce the 
Aqaba thermal power station with extra generating units. The submarine cable connected 
between Taba and Aqaba substations is 13km long and was laid at a depth of 850m 
underwater. Currently, the exchangeable energy between Egypt and Jordan reaches 
130MW, but it is expected to be in the order of 350MW after the completion of the 
project and linking with other countries. 

 

 
Figure 1.  The map of Arab countries with existing and future interconnection. 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

3 2

1

Figure 2.   The stages of the future interconnections among the GCC countries. 

 93



M.H. ABDERRAZZAQ 

 
 Oil Duct 
Copper conductor 
 Carbon paper tapes 
 Impregnated paper        
 insulation 
 Nylon tapes 
 Galvanized steel    
 armour 
  Polypropylene yarn 
and asphalt covering 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 
Figure 3.   Main constituents of the 400kV, oil-filled submarine cable. 

 
 

 

S
Y
R
I
A 

Aqaba    Amman  
station     South 
400kV    400kV 

JORDAN 

400kV 
submarine 

Cable 

RED SEA EGYPT 

Suez     Taba     500/400kV 
500kV  500kV   750MVA 

 
 
 
 
 
 
 
 
 
 

 

Figure 4.  Simplified diagram of the Egypt-Jordan interconnection link. 
 

On the other side of the Arab World, a number of vital projects are currently being 
given increased attention by decision makers. Spain is already supplying Morocco with 
electricity via a 400kV, 26km and 615m deep submarine cable, established between these 
two countries. Morocco’s grid is also interconnected with Algeria and Tunisia, whereas 
Egypt is linked to Libya by a 220kV power line, which allows for 180MW to be 
exchanged between the two countries. This power line covers a distance of 420km along 
the north-western coast from Alexandria to Salloum on the Libyan border. There are also 
plans for the Egyptian and Libyan power networks to be linked to Europe across the 
Mediterranean through Italy. In addition to the eastern link with Europe via Turkey, 
Egypt and Libya can exchange power with Europe through Italy and Spain. For this 
purpose, a 500kV network is being planned linking Egypt and Libya. A 400kV network 
is also being planned to interconnect Libya, Tunisia, Algeria and Morocco, which are 
currently only connected by 220kV lines. This will form the backbone of a 
Mediterranean Power Pool (MPP), which will link the grids of the Middle East, North 
Africa and Europe. According to GOUWS (1999) the anticipated completion date of the 
MPP is 2015. 

 94



ASSESSMENT OF THE ELECTRIC SYSTEMS INTERCONNECTION 

The electric systems in the Gulf region have been growing rapidly in the last two 
decades. The presence of oil prevents any shortage in power plants and spinning reserves 
in these countries. Despite these conveniences, the electric systems in the Gulf countries 
are of great need to have a unified power grid for emergency purposes, for enhancing 
national and local networks and for saving investments, spent in building new power 
stations. It is worth mentioning here, that a number of promising steps have been taken 
by all members of the Gulf Cooperative Council (GCC) countries in this direction. The 
first phase in the Gulf interconnection will link Saudi Arabia, Kuwait, Bahrain and Qatar 
in a 400kV one grid, while the second stage integrates Oman and the UAE into the 
overall grid as shown in Figure 2. The sharing of the transmitted power is based on a 
strategic criterion and mutual benefits of each country (Ibrahim, 1996). However, a 
number of hurdles could cause a delay in the completion of the interconnection in this 
region. Among these problems are the relatively long distances between the countries, 
the presence of some unlinked national grids and the difference in power frequency 
between Saudi Arabia and other Gulf countries. It is worth mentioning here, that these 
problems will not hider the Gulf countries from going on with their recent huge plans and 
investments to reinforce their national grids and to make this interconnection more 
reliable and robust. 

3. Technical Considerations and Network Studies 

The power systems in the Arab countries have been established and developed using 
the experience and consultations of various foreign companies. This fact is clear from the 
differences in the design and ratings of the equipment used and the standards applied in 
the Arab countries. These systems have been working separately for decades without 
having serious complaints. However, when these systems become a part of the 
interconnection, serious technical difficulties are expected to occur. One of the problems 
which faced the initial studies of interconnection was the lack of information, records and 
data, which are considered of great importance for many studies such as protection, 
insulation, coordination and stability studies. Therefore, it is difficult to answer the 
question whether a specific analysis has been performed in the design stage or which 
measures have been made to test the equipment before putting it in operation. To avoid 
this situation in future, the manufacturer should carefully perform the commissioning test 
of the facilities, by installing the suitable recorders and analyzing the test measurements 
precisely (EDF Report, 1998). The main technical difficulties which appeared during the 
initial stages of interconnection or might appear in future, as shown by the simulation 
studies, can be summarized as follows:  

3.1 Power Exchange Problems  

The power exchange limits are determined for the worst case, which can face the 
interconnected system during its operation. Therefore, the criteria applied during the study stage of 
the project were based on the following facts (EDF Report, 1998) : Firstly, the systems loaded at 
the maximum power exchange had to satisfy the security rules following the tripping of one 
internal element. Secondly, the tripping of the interconnection link, loaded at the maximum power 
exchange, should not lead to shedding more than the first step of the underfrequency load shedding 
scheme. Finally, the tripping of the interconnection link loaded at the maximum power exchange 
should not lead to unacceptable overfrequency or overvoltage in power systems. The minimum 
value of the voltage limit, in many cases, cannot be modified to allow more imported power.   
Table 1 provide some values for the possible exchanged power among the systems of Egypt, 
Jordan, Syria and Turkey. Other countries will be included in future in the subsequent stages of this 
interconnection. 
  

 95



M.H. ABDERRAZZAQ 

Table 1:   Expected values of the interchangeable energy among the EJLST countries. 
  

Limits in MW Egypt can 
Import 

Jordan can 
Import 

Syria can 
Import 

Turkey can 
Import 

From Egypt  50 350 350 
From Jordan 260  350 300 
From Syria 250 50  500 

From Turkey 220 50 620  
From E+J   400 450 
From S+T 250 50   

From J+S+T 260    
From E+J+T    700 

 
3.2 Oscillations  

Small inter-area oscillations could appear following the conditions of a short circuit on one of 
the interconnection transmission lines. System configuration, involving different combinations of 
generators, overhead transmission lines and submarine cables may result in such type of problems. 
The simulations performed in the first stage of the EIJLST interconnection between Jordan and 
Egypt showed that these oscillations could be well damped with the existing parameters on both 
sides. Moreover, reinforcing the existing tie lines and enhancing internal systems are important 
means for improving the behavior of interconnected systems.  

3.3 Overvoltages  
One of the problems which frequently occurs during the operation of the interconnection link 

is the long duration temporary overvoltages. This case is usually developed when transformers are 
switched in at AC fault clearing or as a consequence of voltage rises due to load rejection. The 
harmonic currents, generated by the saturated transformer, may coincide with resonance impedance 
points in the system and as a consequence harmonic voltages of high amplitudes will build up. This 
could cause unusual overvoltages of high magnitudes. Resonant overvoltages are particularly of 
great interest, not only when transformers have to be re-energized or during commissioning tests of 
the transformers, but also each time the interconnection link is put into service again after tripping. 
In the case of a near fault clearance in normal operation, the risk of an overvoltage occurrence also 
exists. In this case, the voltage significantly decreases during the fault and suddenly reappears upon 
fault clearance, which can be considered in some conditions almost equivalent to re-energization 
(EDF Report, 1998). 

The steady state overvoltages, associated with the interconnection link must be 
examined with no power exchange between connected systems, which is in fact the worst 
situation to be studied. Simulations are usually performed for faults at different locations 
along the interconnection link. The necessary studies could be performed using 
specialized computer programs such as Electromagnetic Transient Program (EMTP), 
Transient Network Analyzers (TNA) and other simulators. According to the obtained 
results and to avoid the equipment damage, the suitable protection system has to be 
proposed. Therefore, the studies performed for Egypt-Jordan link, came with a proposal 
to install overvoltage relays, set at 570kV at the Suez substation on the Abu Zabal-Suez 
line and at Taba substation on the Suez-Taba line. However, on the Jordan side it was 
necessary to install an intertripping relays at Amman South substation, on the 400kV 
Aqaba-Amman South line. 

3.4    Frequency Excursions 
When the rating of the AC transmission of the interconnection links is considerably higher 

than the small system load, severe frequency excursions could be expected. Ovefrequency could 

 96



ASSESSMENT OF THE ELECTRIC SYSTEMS INTERCONNECTION 

arise after total or partial tripping of the interconnection. In these cases, the turbine governors are 
the only devices capable of controlling and restoring the system frequency, provided that no special 
system control action was taken, such as generator tripping or increasing the available transmitted 
power. 

On the other hand, the underfrequency conditions, which might arise due to some disturbances 
such as the loss of generation units can be easily controlled by shedding some loads according to 
the system’s load shedding scheme. The agreement on a load shedding scheme, common to all 
connected systems is considered one of the important issues which should be reached immediately 
after putting all interconnection links in operation. The tripping of some lines, included in the 
interconnection, will eventually cause some islanding of specific systems with loads of other grids. 
It is necessary in these cases to decide the criterion on which the tripping scheme has been based, 
to avoid complicated schemes and unnecessary shedding of some loads. Table 2 provides some 
Figures for the expected future load shedding scheme. 

 
Table 2:  Load shedding scheme for the current constituents of the EIJLST. 

 
 Frequency Egypt Jordan Syria Turkey 

49.2 
49.1 
49 
49 

48.8 
48.7 
48.6 
48.5 
48.4 
48.2 
48 

47.9 
47.8 
47.7 
47.6 

2% 
3% 
4% 

Link Tripping
10 
20 
20 

 
 

8% 
 

10% 
 

15% 
Link Tripping

2% 
3% 
2% 
7% 
3% 
4% 
4% 

 
 

8% 
 

10% 
 

15% 
Link Tripping 

15% 

 
 

8% 
 

10% 
 

15% 
Link Tripping

15% 
 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 

3.4 Generating Units 
The generating units in interconnected systems have to be operated according to some specific 

conditions. These conditions concern sensitivity to frequency, voltage deviations and the means to 
control active and reactive power. Since the power frequency is common to all units and any drop 
in this frequency due to a loss of generation will influence the whole system, it is vital that all 
interconnection parts should satisfy certain requirements with respect to frequency (E.S.Ibrahim, 
1996). If this factor has not been given the required attention, the most sensitive units may trip 
causing further frequency decay, and in worst cases, this could be developed to cascade tripping 
and blackout. 

Regarding the voltage variations, the short duration dips to certain levels should not 
cause tripping of the unit. The control facilities should be set to keep these units running 
with the highest reliability. This, in fact, depends to some extent on the strength of the 
system. Therefore, when the generator is connected to a weak system, the machine 
voltage is controlled by the automatic excitation system. However, the speed governor 
has the responsibility of controlling the machine speed and consequently the system 

 97



M.H. ABDERRAZZAQ 

frequency. On the other hand, if the generator is connected to a strong system the 
machine voltage and system frequency is almost constant. Consequently, the role of the 
automatic excitation control is to fix the reactive power supplied by the generator to the 
network. 

3.5 Protection System Coordination.  
The main aim of the protection system is to trip the faulty elements in the network and to 

maintain a high level of continuous service.  However, the requirements for the protection can be 
extended to cover more strategic goals such as utilization of reactive power compensators, power 
exchange and load shedding schemes. Since the protection philosophies employed by individual 
systems are different from one system to another, the integration of these systems into a common 
link will not be an easy task. The settings of the protective relays and their coordination procedures 
should be studied carefully prior to the commercial operation of the link. Moreover, the backup 
protection system of the main transmission lines should also be reviewed by all terminals of the 
interconnection. Finally, the difference in the design and the manufacture of the protective 
equipment, employed by various systems involved in the link, can cause some difficulties and false 
operations of the protective relays of connected countries. This needs careful assessment of the 
problem and the problem can be avoided by using unified standards for the equipment in the future. 

4. Conclusions  

To effectively utilize the existing energy resources in the Arab countries, it would be 
necessary to plan the system at a national level and to support the inter-regional links to 
form a unified regional power grid. The integration of individual systems into a single 
grid is associated with new technical problems. Although these difficulties are 
manageable, they must be seriously studied during the preparation stage of 
interconnection. This can be achieved by using advanced simulation techniques, 
computer facilities and other power related software. The deep investigation of these 
technical problems will protect the national grids from frequent disconnections and 
prevents repeated islanding from the main link.  

The interconnection should be employed to unify the power systems in the region in 
respect of standardization, high voltage equipment selection and construction. The 
development of the individual electric systems should come as a first and necessary step 
before interconnection. This comprises the updating of the network configuration, system 
control and protection, which are necessary for the stability and robustness of future 
interconnection network. 

References 

ABDERRAZZAQ, M. and ALZAHAWI, B., 1996. The Jordan-Egypt Red Sea Cable 
Interconnection Project. Proceedings of the sixth IEE Conference ”AC and DC 
Power Transmission Conference” Publication No 423, 29Apr-3May 1996, London, 
124-127. 

AMRO, K., (Editor). 1997. Electrical Energy Bulletin of the Arab Countries. Arab Union 
of Producers, Transporters and Distributers of Electricity. Amman, Jordan. 

EDF Report, 1998. Operational Studies for the interconnection of the power systems of 
the EIJLST Countries. 

GOUWS, M., 1999. Egyptian Power Surge. African Energy Magazine,1, No1,South 
Africa. 

IBRAHIM, E.S., 1996. Interconnection of Electric Power Systems in the Arab World.  
IEE Power Engineering Journal, 121-127. 

SACKEY, T. and ZAKHARY, S.Z., 1996. Power Wheeling Through the West African 
Interconnected System. Proceedings of the sixth IEE Conference ”AC and DC 

 98



ASSESSMENT OF THE ELECTRIC SYSTEMS INTERCONNECTION 

Power Transmission Conference” Publication No 423, 29Apr-3May, 1996, London, 
13-18. 

 
 
 
Received 22 June 2001    
Accepted 13 December 2001     
 
         

 
 

 99


	Assessment of The Electrical Systems Interconnection in The Arab World
	M.H. Abderrazzaq
	
	
	
	
	Hijjawi Faculty for Engineering Technology, Yarmouk University, Irbid 21110, Jordan,
	Email: abder@maktoob.com.





	Overview of the Interconnections Among the Arab Countries
	Technical Considerations and Network Studies
	Power Exchange Problems
	The power exchange limits are determined for the worst case, which can face the interconnected system during its operation. Therefore, the criteria applied during the study stage of the project were based on the following facts (EDF Report, 1998) : Fir
	Oscillations
	Small inter-area oscillations could appear following the conditions of a short circuit on one of the interconnection transmission lines. System configuration, involving different combinations of generators, overhead transmission lines and submarine cable
	Overvoltages
	One of the problems which frequently occurs during the operation of the interconnection link is the long duration temporary overvoltages. This case is usually developed when transformers are switched in at AC fault clearing or as a consequence of voltage

	When the rating of the AC transmission of the interconnection links is considerably higher than the small system load, severe frequency excursions could be expected. Ovefrequency could arise after total or partial tripping of the interconnection. In thes
	Generating Units
	The generating units in interconnected systems have to be operated according to some specific conditions. These conditions concern sensitivity to frequency, voltage deviations and the means to control active and reactive power. Since the power frequency
	Protection System Coordination.
	The main aim of the protection system is to trip the faulty elements in the network and to maintain a high level of continuous service.  However, the requirements for the protection can be extended to cover more strategic goals such as utilization of rea
	Conclusions

	References