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International Journal of Energy Economics and Policy | Vol 10 • Issue 3 • 2020 471

International Journal of Energy Economics and 
Policy

ISSN: 2146-4553

available at http: www.econjournals.com

International Journal of Energy Economics and Policy, 2020, 10(3), 471-475.

Toward Developing Energy Star Rating Development in Jordan

Majeda Yakhlef1, Yazeed Yasin Ghadi2, Ali M. Baniyounes1*, Mazen Alnabulsi1, Eyad Radwan1

1Department of Architecture and Electrical Engineering, Applied Science Private University, Jordan, 2Software Engineering and 
Computer Science, Al Ain University of Science and Technology, UAE. *Email: al_younes@asu.edu.jo

Received: 31 March 2019 Accepted: 15 December 2019 DOI: https://doi.org/10.32479/ijeep.7982

ABSTRACT

The objective of this article is to provide an efficient means of enforcing green building in Jordan, the Middle East. The paper is proposing assessment 
tool of Energy Star Rating Scheme and also explaining its role for achieving sustainable development during buildings lifecycle and hence reducing 
energy and water usage. The scheme development will remove considerable environmental, social and economic issues as Jordan is a country that 
renowned for its poor energy and water resources. The article provides technical aspects, means, technologies and processes for proposing and 
implementation green star ratings for buildings. The star ratings are based on integrating renewable energy technologies, water recourses and its 
consumption management and waste recycling and its management throughout the buildings’ life cycle including its design, installation and operation.

Keywords: Energy Star Ratings, Energy and Water, Sustainable Energy, Environment 
JEL Classifications: K32, O13

1. INTRODUCTION

In Jordan, buildings and building’s sector including domestic and 
commercial buildings is responsible for large portion of energy 
consumption. Energy consumption in buildings consumes up to 
40 of total energy usage around the globe Baniyounes et al. (2012) 
and this is expected to increase by almost 20% in the next two 
decades as announced by Fumo and Biswas (2015). buildings 
heating, ventilation, and air conditioning (HVAC) is the biggest 
energy consumer which accounts for almost 35% of total energy 
consumption within building Kordjamshidi et al. (2005) and this 
is due to the increase in using energy in residential buildings. 
The previous fact is show how it is necessary to look for energy 
efficient architectural design and development which is based 
on renewable energy and passive energy harvesting techniques. 
After fuel sore prices researchers have emphasized the obligation 
of sustainable and energy efficient development in order to 
lessen energy usage and also minimizing its negative impact on 
the environment by reducing greenhouse gas (GHG) emissions. 
Accordingly, priority and advantages are always provided to 

energy efficient design and development in both residential and 
commercial buildings sector.

Nowadays there are significant numbers of computer aided software 
and programs are used to project, evaluate and estimate energy 
usage during design phase. Those software packages are used 
in order to determine best scenario possible of design that used 
minimum energy such as revit, three dimension (3D) studios and 
etc. In this article, buildings energy star ratings (BESR) is highly 
encouraged and recommended to be developed and used extensively 
specially when obtaining buildings permit and necessary licensing 
of operation as this will force developers and stakeholders to save 
energy and force sustainable designs throughout the country taking 
into account here that the software packages and computer programs 
are built in a way that it does meet the country codes and policy 
in regards energy and energy consumption and hence its negative 
impact on the environment which is represented by GHG emissions.

A standard BESR is able to supply necessary data and information 
about buildings’ sustainable and energy efficient design and its 

This Journal is licensed under a Creative Commons Attribution 4.0 International License



Yakhlef, et al.: Toward Developing Energy Star Rating Development in Jordan

International Journal of Energy Economics and Policy | Vol 10 • Issue 3 • 2020472

level (how efficient or how sustainable is the design) for example a 
one-star rating is a building that achieve minimal energy efficiency 
design requirement and 6-star rating is the building design that 
it does consider all requirements of energy and sustainability 
requirements design. In short, the star rating task will be carried on 
by assessing energy efficiency compared to standard buildings design 
and development also the system will be able to compare between 
buildings in regards of its gross energy and water usage necessities.

Consequently, an efficient buildings’ star rating scheme will inspire 
architects, developers and designers to focus on energy efficiency and 
sustainability in their design, and to take advantages of renewable and 
passive harvesting and preserving techniques which currently without 
compromising indoor thermal comfort and indoor air quality (IAQ).

Throughout literature there are a numerous amount of research, 
articles and activities including websites development. Worth 
mentioning have publish an article in regards how architects and 
designer have better understanding on energy efficiency and the 
sustainable measures and conservation Shaikh et al. (2017). Also 
Zuo et al. (2017) has developed a star rating guides for concrete 
buildings. In addition, Illankoon et al. (2017) have showed an 
important about green buildings evaluation from life cycle view.

Jordan is classed between those countries with minimal energy 
and water resources and hence lowest per capita base. The 
situation is getting worse due to demographic growth as a result 
of refugee flux from neighboring countries e.g. Syria and Iraq 
the situation is expected to get poorer. The scarcity of energy 
recourses in Jordan is the country most significant restrains and 
challenge as the country’s growth and development is absolutely 
depends on energy availability and hence very important factor 
of economic improvement. However, the most of research 
activities hardly mention the situation in the Middle East specially 
Jordan. Accordingly, this article will discuss and propose a new 
building, star ratings which is based on energy efficiency, water 
management, waste management and sustainability.

The main intention of this research study is to evaluate the 
suitability of buildings by applying star rating schemes in buildings. 
This rating is evaluated based on the installation, operation, 
consumption and monitoring of energy, water resources and waste 
management data. Knowing that, green or sustainable building is 
buildings that consider certain criteria and techniques are integrated 
in buildings which conserve energy, water resources and waste 
management, building architecture, landscaping, maintenance and 
housekeeping in order to guarantee sustainable future. These criteria 
and techniques will include sustainability measure on buildings 
planning, design and installation, buildings architecture including 
nature and location, water and energy resources, the usage of 
renewable and passive technologies, and related GHG emissions.

2. DEVELOPMENT OF BUILDINGS’ 
ENERGY RATING EVALUATING SCHEME

Buildings energy rating evaluating scheme is a basic measure 
that assess energy efficiency of newly constructed or existing 
building and its associated GHG emission. The assessment basis is 

including energy will be used by lighting, HVAC, water pumping 
and firefighting system and also its associate cost, emissions and 
its projected efficiency. BESR are applied widely and effective 
in various countries such as Australia and New Zealand Le et al. 
(2018). BESRs are constructed to project energy consumption and 
its GHG requirements in order to issue a certificate. Overall BESRs 
are regarded whilst looking for an optimum objective in order to 
reduce energy consumption and its related standards throughout 
applying sets of energy efficient tools and scenarios. These tools 
are regarded as inclusive environmental evaluation scheme such as 
BREEAM (United Kingdom) BREEM (2019), GBTool (Canada) 
Gu (2018), leadership in energy and environmental design (LEED) 
(US) LEED (2019) and etc. the previously mentioned bodies 
assessment tools and scenarios are based on life cycle analysis and 
for the buildings’ sectors. The majority of these processes have 
intended to be utilized for the process of choosing and deciding 
buildings’ design, materials, energy supply and resources including 
renewable energy, waste management including recycling and 
transport Ali and Al Nsairat (2009). In addition to the previously 
mentioned bodies there are a significant number of software and 
computer aided tools applied in this field such as EnergyPlus, 
TRNSYS, REVET, 3D studio, and etc.

The most of those software packages utilize factual models, in 
a way that the buildings data and its technical specifications 
are evaluated digitally and then added on and implemented in a 
mathematical model in order to simulate the buildings’ indoor 
thermal and visual comfort Kordjamshidi et al. (2005). Also, 
all information and data about the local climatic are utilized 
and modeled and then its effect on the building climate and its 
energy usage can be evaluated and computed based on projected 
conditions and activity so indoor occupation density and indoor 
activity are both considered. The local governmental and unions 
authorities in Jordan are all invited to develop BSERs and enforce 
this BSER in all future design and developments. Currently there 
are a wide range of buildings’ energy and water usage easement 
tools are existed. Those tools are ranged from simple tools to very 
sophisticated ones that able to simulate the whole of the building 
and hence virtual reality simulation tools.

3. BUILDINGS STAR RATING STRUCTURE

Globally, the common method of buildings’ star ratings index 
is based on energy usage, energy efficiency, water usage and 
water recycling and waste management. This rating index will 
mostly depend on energy usage. Commercial buildings use the 
most of energy in every single local markets taking into account 
that, more than 40% of this energy is used by buildings, HVAC 
system Baniyounes et al. (2013) taking into account here that 
index completely depends on the conditioned space gross area and 
its volume. It has been reported by Lo (1995) that smaller areas 
and volume is the main factor of HVAC systems energy usage. 
One of the reasons behind the previously mentioned fact that 
the buildings’ envelop and volume ratio as small buildings have 
bigger ratio Kordjamshidi et al. (2005). In addition Giridharan 
and Emmanuel (2018) have reported that contents and textile heat 
flux per floor area unit is higher in small houses than big ones. 
According to Mattoni et al. (2018) and Giridharan and Emmanuel 



Yakhlef, et al.: Toward Developing Energy Star Rating Development in Jordan

International Journal of Energy Economics and Policy | Vol 10 • Issue 3 • 2020 473

(2018) the buildings’ cooling load conditions of bigger buildings 
with higher energy star ratings e.g. 5-or 4-star rating were found to 
be significantly lower to buildings with low 3-star ratings, which 
becomes lately applicable in too many countries around the globe.

3.1. Buildings Sustainable Design and Planning
With the intention to reduce the effect of buildings development 
negative impact on the environment and local areas, several 
policies and recommendations were developed as a guide for 
ERES such as segregation of buildings’ by constructing and 
installing dust filter around the construction site area in order to 
avoid the environment air pollution and the spell of contamination 
resulted from construction. In addition, good quality soil should 
be dig out, and stored in order to preserve it outside the concerned 
buildings’ construction site. Additionally, and in order to protect 
trees, a loss control mechanism must be implemented also trying 
the best possible way to keep around the construction site safe. 
Also, ERES must seek the increment of buildings’ structural 
strength meanwhile and minimizing heat effect that will be caused 
by hard pavement and concrete usage throughout buildings. It is 
worth mentioning her that Vyas et al. (2014) have advised that 
gross paving throughout newly constructed buildings should not 
exceed more than 17%, also not more than 50% of the pavement 
areas protected by sun blockers and trees. ERES also must mind 
irrigation water so it should also be reduced to around 50%.

3.2. Energy Conservation
Buildings’ energy conservation is defined as the all sort of activity 
that has been made in order to minimize energy consumption 
in buildings. This could be done throughout the buildings by 
consuming energy efficiently meanwhile keeping in mind lowering 
the volume of required services expected to be used such as 
reducing HVAC and lighting load. Energy conservation minimizes 
the usage of fossil fuel and also minimize its negative impact on 
the environment. Additionally, it lesser buildings’ operational 
cost by cutting off fossil fuel energy costs. Moreover, energy 
conservation can be achieved by minimizing waste and reducing 
energy losses, developing energy efficient technical systems, its 
maintenance and operation.

3.3. Renewable Energy Technologies
Renewable energy technologies that can be used within buildings’ 
applications and systems are solar energy includes thermal and 
photovoltaic, wind energy, geothermal energy, as well as bio-
mass energy. In order to select proper renewable energy system to 
operate to existing building or to newly designed or constructed 
building, it is significant to investigate various existing conditions 
e.g. technologies market availability, available renewable 
energy resources, the technologies’ required space and available 
space for technologies’ within the building, energy cost from 
author providers, tax and incentives availability based on using 
renewable energy technologies, buildings’ aesthetics and its unique 
architectural features.

3.3.1. Photovoltaic systems (PV)
PV panels are a technology where the sun radiation is converted 
into electricity. In PV systems, solar panels are connected together 
to make up what called solar modules. Next solar modules are 

connected together to form what called solar arrays where they 
can be mounted on buildings’ roof or round it as shown in Figure 1 
Sousa et al. (2019). A power inverter converts the direct current 
generated by the system into grid-quality alternating current 
electricity.

3.3.2. Solar thermal energy
The production of hot water and hot air using the sun power 
are economic, cost-competitive and environmentally friendly 
technique where there is no need for electricity or conventional 
fossil fuel for the production process.

Whether heating water or air, the heat is produced by solar collectors 
where the heat is absorbed by those collectors and then is transferred 
the heat to air or water. In some cases, especially when heating 
water, the hot is then is stored in a tank until used. The previously 
mentioned systems are classified upon the output temperature 
namely low collectors’ temperature e.g. Flat plate collectors 
where output is ranged from 50°C to 90°C, medium collectors’ 
temperature e.g. evacuated tube collectors where output is ranged 
between 90°C and 250°C and high collectors’ temperature e.g. open 
trough collectors where output is above 250°C. Despite the high 
temperature of the open trough collector’s temperature, the most 
suitable collectors in buildings are flat plate collectors and evacuated 
tube collectors as shown in Figure 2 Mesthrige and Chan (2019).

3.3.3. Other renewable energy recourses
The other renewable energy recourses that can be are including 
wind energy and bioenergy. Wind energy is generated by equal 
heating of the earth’s surface by the sun creating wind current. 
The wind current which comes in the form of motion or motion 
energy, can be exploited by wind turbines generating electricity 
using rotating blades. However, installing wind turbine in the top 
of buildings require mega structure requirements as well as big 
acoustic protection requirements due to the blades noise during 
movement accordingly using wind energy is not common.

Bioenergy depends on organic materials e.g. as plantations, excess 
from farming, agriculture and forestry, as well as the organic 
matters of metropolitan including manufacturing wastes which 
normally utilized in order to generate fuel, and thus energy. Using 
bioenergy within buildings is possible but, the process requires 
big capital that will increase the cost on stakeholders.

3.3.4. Mechanical ventilation versus natural ventilation of 
buildings rating index
Naturally ventilated buildings main advantages are to reduce 
energy consumption while improving IAQ. IAQ mainly depends 
on using and circulating outdoor fresh air inside building. The more 
of fresh air is used and circulated, the better is IAQ. Buildings’ 
natural ventilation performance is mainly depending on various 
conditions such as winds’ speed and winds’ direction, mostly round 
reference buildings causing what known as microclimate change 
Hang et al. (2012). If a new large-scale tower is placed amongst 
a large city of low-rise buildings, the effect of the new building 
on the UHI, on the wind in the street and the structure of the lapse 
rate of temperatures is problematic. This paper is exploring what 
the literature can tell us on this subject Hayter and Kandt (2011).



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International Journal of Energy Economics and Policy | Vol 10 • Issue 3 • 2020474

3.3.5. Water management and conservation
Water and water availability are a prime element for mankind 
survivor and his existence as well as people important several 
interests around the globe. Jordan as a country is renowned for 
water scarcity which mandate the importance of water portable 
water generation and the possibility of its recycling and thus, 
this will lead to reduction in energy usage and also reduction of 
GHG emissions and its negative impact on the environment. The 
previous highlighted fact makes water usage conservation and 
management including its recycling a very important factor of 
sustainable development and its assessment.

Buildings are a big water consumer which accounts for about 
about 16% of freshwater usage. Consequently, enormous 
weight is set to water usage, conservation, management and 
efficiency as the at most sustainability buildings rating factor 
around the globe. Consequently, there are enormous buildings’ 
sustainability evaluation indicator tools Sousa et al. (2019). 
Water sustainability indicators concentrate on various fields of 
buildings’ sustainable developments also they are planned to 
fit most of existing developed buildings or newly constructed 
ones Mesthrige and Chan (2019). An example of those water 
sustainability indicators or rating schemes are Building Research 
Establishment (BREEM) Environmental Assessment Method 
which was established in the year 1992, followed by LEED 
which was initiated in the United States of America in the year 

1996 and as well the establishment of Green Star Australia in 
the year 2003 and etc.

3.3.6. Waste management
Sustainable buildings as well as renowned for their environmentally 
friendly and green structuring in addition to its consumables 
resources waste efficient management during the buildings’ life-
cycle which range from between the design process, construction 
and installations, readiness and operation, scheduled and 
emergency maintenance, after words renovation, and usable waste 
and its management. Nowadays the environment problems and 
the distress for sustainability is inspiring efficient consumption 
and management of energy, water and consequent waste 
management, to guarantee the avoidance of any type of waste, 
implement environmentally reasonable and economic as well as 
environmentally friendly building’s execution including its design, 
the process of construction and required operation.

4. CONCLUSION

This study has proposed initial ratings regarding buildings’ energy, 
water resources and waste management, building architecture, 
landscaping, maintenance and housekeeping status in order to 
encourage more sustainable and green building in Jordan, the 
Middle East.

The purpose of buildings green star ratings is to encourage 
the development of the global built in environment regarding 
sustainability and environmentally friendly installations 
given significant priority to energy, water resources and waste 
management, building architecture, landscaping, maintenance 
and housekeeping status of buildings. The study has highlighted 
the base that should be implemented in sustainable buildings 
and thus its evaluation based on energy including the utilization 
of renewables, mechanical and natural ventilation, water 
management, and waste management. In addition, this study 
provides the at most aspects of all designs of green and sustainable 
buildings developments and its ratings in Jordan.

Introducing criteria for star green buildings’ ratings will 
significantly push through towards enhancing an improve 
buildings’ energy and water management performance and hence 
reducing nonenvironmental friendly GHG without comprising 
indoor and outdoor comfort condition in order to save energy 
and water.

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Figure 2: Evacuated tube collectors



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