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THE EFFECT OF VARIOUS TYPES OF BUILDING ROOF MATERIALS
ON THE COOLING LOAD
RAHEEM KADHIM AJEEL ALJEBUR
A thesis submitted in fulfillment of the requirement for the award of the
Degree of Master of Engineering
Faculty of Mechanical and Manufacturing Engineering
University Tun Hussein Onn Malaysia
JULY 2015
v
ABSTRACT
Roof insulation is one of the most important strategies to reduce the electricity
consumption in the building which lead to cost savings and reduce the emission of gases
that pollute the environment directly. Therefore, Building information modelling took
great interest in recent years in the world in terms of the design simulation of the
buildings and choose the best design. This study aimed to evaluate the effect of various
types of building roof materials on the cooling load. This study involved in selecting a
particular building type (factory building) and the effect of the cooling load by using a
various metal deck roofing with and without insulation. Case study in this project is a
simple factory building consists of two floors, ground floor is a production space and the
first floor is the factory's offices. The cooling load requirement for the building was
calculated by using Auto desk Revit software. The results indicated that roof insulation
is one of the most important strategies to reduce the cooling load and enhanced the
electricity consumption in the building. 20% reduction in the space cooling lead to cost
savings and reduce the emission of gases that pollute the environment directly.
vi
ABSTRAK
Penebat bumbung adalah satu daripada strategi penting untuk mengurangkan pengunaan
elektrik dalam bangunan yang membolehkan penjimatan kos dan mengurangkan
pengeluaran gas yang mencemarkan persekitaran secara terus. Oleh itu, membina
informasi model mengambil minat besar pada tahun terkini dari segi rekabentuk
simulasi bangunan dan memilih reka bentuk terbaik. Kajian ini bertujuan untuk menilai
kesan daripada pelbagai jenis bahan atap bangunan terhadap beban sejuk. kajian ini
melibatkan pemilihan sesetengah jenis bangunan(bangunan kilang) dan kesan daripada
beban penyejukan mengunakan perbagai jenis bahan lapisan bumbung dengan penebat
dan tampa penebat. Projek ini melibatkan bangunan kilang yang mempunyai dua tingkat,
tingkat bawah adalah ruang pengeluaran dan tingkat atas adalah pejabat kilang.Beban
penyejukan yang diperlukan untuk bangunan dikira mengunakan aplikasi Auto desk
Revit. Keputusan menunjukkan penebat bumbung adalah satu strategi yang sangat
penting untuk mengurangkan beban penyejuk dan mengurangkan penggunaan elektrik
dalam bangunan. 20 % pegurangan pada ruang penyejukan membantu pengurangan kos
dan mengurangkan pengeluaran gas yang mencemarka alam sekitar secara terus.
vii
CONTENTS
TITLE I
DEDICATION III
ACKNOWLEDGEMENT IV
ABSTRACT V
LIST OF CONTENTS VII
LIST OF TABLES XI
LIST OF FIGURES XIII
LIST OF SYMBOLELS XV
LIST OF APPENDIX XVIII
CHAPTER 1 INTRODUCTION 1
1.1 Introduction 1
1.2 Problem of study 3
1.3 Objectives of study 3
1.4 Scope of study 3
CHAPTER 2 LITERATURE REVIEW 4
2.1 Literature review 4
2.2 Introduction 5
viii
2.3 Components of air conditioning system 6
2.4 The roofs effect on the cooling load 7
2.4.1 Roof materials 8
2.4.2 Roof colour 10
2.4.3 The angle of inclination in roof 12
2.4.4 Cool roofs 14
2.5 Applications of air conditioning 16
2.6 Insulation 17
2.6.1 Generic types of insulation 18
2.6.2 Generic forms of insulation 19
2.6.3 Thermal insulation 19
2.6.4 Principles of insulation 20
2.6.4.1 Heat transfer 20
2.6.4.2 Requirements of an insulant 22
2.6.5 Insulation Product selection 22
2.7 Polystyrene foam insulation 25
2.7.1 Optimizing insulation with polystyrene foam 26
2.7.2 Key properties of polystyrene foam 28
2.8 Energy demand of buildings 29
2.8.1 Electricity consumption 30
2.8.2 Air conditioning 31
2.9 Related work 32
ix
CHAPTER 3 METHODLOGY 36
3.1 Introduction 36
3.2 Flow chart 39
3.3 Methods of estimating cooling loads 40
3.4 Cooling load calculations 41
3.4.1 External loads 42
3.4.1.1 Heat transfer through opaque surfaces 42
3.4.1.2 Heat transfer through fenestration 44
3.4.1.3 Heat transfer due to infiltration and ventilation 45
3.4.2 Internal loads 49
3.4.2.1 Load due to occupants 49
3.4.2.2 Load due to lighting 51
3.4.2.3 Internal loads due to equipment and appliances 52
3.4.3 The total load 54
3.5 Autodesk Revit software 54
3.6 Case study 56
3.6.1 Data 56
3.6.2 Layout 59
3.6.3 Roof and wall layers 60
3.7 Method 62
3.8 Application of Autodesk Revit software 63
3.8.1 Simulation of building model/parameters 64
3.8.2 Setting information 65
x
CHAPTER 4 RESULTS AND DISCUSSIONS 71
4.1 Introduction 71
4.2 Building element model 72
4.3 Simulation results 72
4.3.1 Cooling load saving 72
4.3.2 Effect of insulation on roof heat transmission 74
4.3.3 The effect of the cooling load on the electricity 76
consumption with and without insulation
4.3.4 Monthly peak demand 79
4.3.5 Cost and saving 80
CHAPTER 5 CONCLUSION 82
5.1 Introduction 82
5.2 Conclusion of the study 83
5.3 Study contribution 84
5.4 Future works 84
REFERENCES 85
APPENDIXE 90
xi
LIST OF TABLES
PAGE
3.1 Shading coefficients for glass without or with interior shading devices 45 46
3.2 Maximum solar heat gain factor (SHGFmax) for sunlit glass, north 45 46
latitudes
3.3 Cooling load factor (CLF) for glass with interior shading and 46 47
location in north latitudes
3.4 Total heat gain, sensible heat gain fraction from occupants 50 51
3.5 CLF for occupants 51 52
3.6 CLF for lighting 52 53
3.7 Typical appliance load 53 54
3.8 Weather conditions in Batu Pahat city included temperature and 56 57
huimidty
3.9 Data for machine and equipment 58 59
3.10 Details for zone 1 (Ground floor) and zone 2 (1st.floor) 68 69
4.1 The building cooling load for roof with and without insulation 74 75
4.2 Cooling load of the roof of the factory building with and without 76 77
insulation
4.3 The electricity consumption of the factory building with and 78 79
without insulation
xii
LIST OF FIGURES
2.1 Thermal radiation from roof into interior 8
2.2 The angle of inclination in roof 13
2.3 Roof with conventional paint (a) and with cool roof paint (b) 14
2.4 Granular insulation a, cellular insulation b, and fibrous insulation c 18
2.5 Extruded polystyrene foam board (a) and expanded polystyrene 27
foam board (b)
2.6 Measured consumption of electricity, heat and water heating in an Office 31
building with passive house standard in Weilheim-Teck, Germany
2.7 Cooling energy demand for various sectors in Germany 32
3.1 Difference between instantaneous heat gain and cooling load as a result 38
of heat storage effect
3.2 Process flow chart of project 39
3.3 Various components of cooling load 42
3.4 First floor (Administrative Area) 59
3.5 Ground floor (Production Area) 60
3.6 Wall layers 60
3.7 Roof layers 61
3.8 The roof of factory building without the insulating material 62
3.9 The roof of factory building with insulating material 63
xiii
3.10 Assembly roof layers 64
3.11 Assembly walls layers 64
3.12 The factory building 3D model 65
3.13 The location of the factory building 66
3.14 Cooling design temperatures 66
3.15 Space setting 67
3.16 Zone setting 67
3.17 Identification of space type 69
3.18 Identification of lighting and power 69
3.19 Identification of number of peoples 70
3.20 Identification of indoor design conditions 70
4.1 Building monthly cooling load with and without insulation 73
4.2 Cooling load of the roof with and without insulation 75
4.3 Monthly electricity consumption with and without insulation 77
4.4 Electricity consumption saving 79
4.5 Monthly peak demand of electricity with and without insulation 80
4.6 Annually Cost and saving of the factory building with and without 81
insulation
xiv
LIST OF SYMBOLES AND ABBREVIATIONS
ASHRAE American Society of Heating, Refrigerating and Air Conditioning
HVAC Heating, Ventilation and Air Conditioning
EPS Expanded Polystyrene
XPS Extruded Polystyrene
IRMA Inverted Roof Membrane Assembly
CLTD Cooling Load Temperature Difference
SHGF Solar Heat Gain Factor
TFM Transfer Function Method
U The overall heat transfer coefficient
A Area
∆T The temperature difference
SHFGmax The Maximum Solar Heat Gain Factor
SC Shading Coefficient
CLF The Cooling Load Factor
The amount of air infiltration
v Wind speed m/s
ρ Air density kg/m3
V The volume of the space adjuster
The sensible heat transfer rate due to infiltration and ventilation
xv
The latent heat transfer rate due to infiltration and ventilation
Specific heat of the air
The amount of air ventilation
Latent heat of vaporization of water at room temperature
, The outdoor and indoor humidity, respectively
The outdoor and indoor dry bulb temperatures
Sensible heat transfer due to the occupants
Latent heat transfer due to the occupants
xvi
LIST OF APPENDICES
APPENIDEX TITLE PAGE
A Styrofoam Brand Roof mate (Extruded polystyrene foam insulation) 90
B Steel roof deck considerations 92
C Euro steel-aluminum sheet 94
D Energy analysis result (use electricity) 96
1
CHAPTER 1
INTRODUCTION
1.1 Introduction
Air-conditioning is a process that simultaneously conditions air; distributes it combined
with the outdoor air to the conditioned space; and at the same time controls and
maintains the required space’s temperature, humidity, air movement, air cleanliness,
sound level, and pressure differential within predetermined limits for the health and
comfort of the occupants, for product processing, or both (Kreith, F. 1998).
Air-conditioning System consists of components or equipment connected in
series to control the environmental parameters. An air-conditioning system, by
ASHRAE (American Society of Heating, Refrigerating and Air-Conditioning Engineers)
definition is a system that must accomplish four objectives simultaneously. These
objectives are to control, air temperature, air humidity, air circulation; and air quality.
The cooling is typically done using a simple refrigeration cycle, but sometimes
evaporation is used, commonly for comfort cooling in buildings and motor vehicles. In
construction, a complete system of heating, ventilation and air conditioning is referred to
as "HVAC".
2
Cooling load is the rate of heat which must be removed from the space to maintain a
specific space air temperature and moisture content (ASHRAE, 2005). The parameters
affecting cooling load calculations are numerous, for example, the outside air
temperature, the humidity ratio, the number and activity of people and etc. These
parameters are often difficult to precisely define and always intricately interrelated.
Many cooling load components vary in magnitude over a wide range during a 24 hr
period. These cyclic changes in load components are not often in phase with each other.
Each must be analyzed to establish the maximum cooling load for a building or zone.
Moreover effects of thermal accumulation also involve in calculating procedure.
Therefore various models and assumptions are developed. The estimated results at the
specific time of calculation are normally expected and not the exact ones (Tongshoob
&Vitooraporn, 2005).
Insulation of building envelopes, both opaque and transparent, is an important
strategy for building energy conservation. Insulation of walls, roof, attic, basement walls
and even foundations is one of the most essential features of energy efficient homes. In
addition, as glass is a poor insulator, insulating transparent envelopes, windows and
skylights, significantly reduces heat loss and gain during the winter and summer (Jong et
al., 2009).
The insulation strategy of a building needs to be based on a careful
consideration of the mode of energy transfer and the direction and intensity in which it
moves. This may alter throughout the day and from season to season. It is important to
choose an appropriate design, the correct combination of materials and building
techniques to suit the particular situation.
3
1.2 Problem of study
This study focused on reducing the electrical consumption for various environmental
condition by optimizing the cooling load of a building. The issue in this research is that
of enhancement the cooling performance by mean of using insulator.
1.2 Objectives of study
The objectives of the study are:
1. To calculate the cooling load of a building for various environment
conditions.
2. To investigate the effect of using various types of roof material with and
without insulator in the building on the cooling load.
1.3 Scope of study
The scopes of study are as follow:
1. Calculate the cooling load of a simulated factory building for 12 months in the
district of Batu Pahat, Malaysia by using Autodesk Revit software.
2. Compare the cooling load of the factory building of a particular type of roof with
and without roof insulator and the saving in electrical energy.
3. The roof layers consisting of metal deck, polystyrene foam (three thicknesses
1.6, 5 and 10 mm respectively) and aluminum sheet.
CHAPTER 2
LITERATURE REVIEW
2.1 Literature Review
This chapter presents an overview of the major concepts related to air conditioning
system, cooling load, the effect of roofs insulation on the cooling load and the
interactions between them.
2.2 Introduction
Full air conditioning implies the automatic control of an atmospheric environment either
for the comfort of human beings or animals or for the proper performance of some
industrial or scientific process. The adjective 'full' demands that the purity, movement,
temperature and relative humidity of the air be controlled, within the limits imposed by
the design specification. For certain applications, the pressure of the air in the
environment may also have to be controlled.
5
Air conditioning is often misused as a term and is loosely and wrongly adopted to
describe a system of simple ventilation. It is really correct to talk of air conditioning
only when a cooling and dehumidification function is intended, in addition to other aims.
This means that air conditioning is always associated with refrigeration and it accounts
for the comparatively high cost of air conditioning.
Refrigeration plant is precision-built machinery and is the major item of cost in
an air conditioning installation, thus the expense of air conditioning a building is some
four times greater than that of only heating it. Full control over relative humidity is not
always exercised, hence for this reason a good deal of partial air conditioning is carded
out; it is still referred to as air conditioning because it does contain refrigeration plant
and is therefore capable of cooling and dehumidifying.
The ability to counter sensible and latent heat gains is, then, the essential feature
of an air conditioning system and, by common usage, the term 'air conditioning' means
that refrigeration is involved (Jones, 2001).
In modern times the term has been applied to year-round heating, cooling,
humidity control, and ventilating required for desired indoor conditions. In other words,
air conditioning refer to the control of temperature, moisture content, cleanliness, air
quality, and air circulation as required by occupants, a process, or a product in the space.
This definition was first proposed by Willis Carrier, an early pioneer in air conditioning
(McQuiston, F. C. et al., 2005).
Generally, air conditioning is the process of treating air in an internal
environment to establish and maintain required standards of temperature, humidity,
cleanliness and motion (Pita, E. G., 2002). These control parameters are:
1. Air Temperature: the temperature is controlled by heating or cooling the air.
2. Air Humidity: the humidity, the water vapor content of the air, is controlled by
adding or removing water vapor from the air (humidification or dehumidification).
3. Air Cleanliness: air cleanliness, or air quality, is controlled by either filtration, the
6
removal of undesirable contaminants using filters or other devices, or by means
of ventilation i.e. the introduction of outside air into the space which dilutes the
concentration of contaminants. Often both filtration and ventilation are used in
an installation.
4. Air Motion: air motion refers to air velocity and to where the air is distributed. It’s
controlled by appropriate air distributing equipment.
2.3 Components of air conditioning system
Heat always travels from a warmer to a cooler area. In winter, there is a continual heat
loss from within a building to the outdoors. If the air in the building is to be maintained
at a comfortable temperature, heat must be continually supplied to the air in the rooms.
The equipment that furnishes the heat required is called a heating system (Bali, 2005).
In summer, heat continually enters the building from the outside. In order to
maintain the room air at a comfortable temperature, this excess heat must be continually
removed from the room. The equipment that removes this heat is called a cooling
system.
An air conditioning system may provide heating, cooling, or both. Its size and
complexity may range from a single space heater or window unit for a small room to a
huge system for a building complex.
Most heating and cooling systems have at a minimum the following
basic components (Pita, E. G., 2002):
1. A heating source that adds heat to a fluid (air water, or steam)
2. Cooling source that removes heat from a fluid (air or water)
3. A distribution system (a network of ducts or piping) to carry the fluid to the
rooms to be heated or cooled.
4. Equipment (fans or pumps) for moving the air or water.
7
5. Devices (e.g., radiation for transferring heat between the fluid and the room).
2.4 The roofs effect on the cooling load
In tropical countries, including Malaysia, Iraq, which is characterized by its climate heat
and long-term drought during the summer season or during the year, the roof ceiling is
the most important elements affecting the thermal environment inside buildings because
it receives large amounts of solar radiation.
For buildings in equatorial regions with warm and humid climate such as
Malaysia, the roof has been said to be a major source of heat gain. Solar protection of
the roof remains one of the main concerns in the thermal design of buildings in the
region (W. Puangsombut et al., 2007; Francois et al., 2004; Olgyay,1992; Koenigsberger
et al., 1980). Previous studies have shown that in Malaysian building, roof has a huge
impact on the thermal performance of the whole building (Badrul et al., 2006; Nor,
2005). Due to its geographical location, Malaysia receives the sun directly overhead
most of the day throughout the year. Therefore, major heat gain of Malaysian houses
comes from the roof. According to previous studies, around 87% of heat transfer from
the roof to occupant is through radiation process, whereby only around 13% of heat is
transferred through conduction and convection (Cowan, 1973), as illustrated in Figure
2.1 The radiant heat received by the occupants in a space can be measured as mean
radiant temperature (MRT).
The mean radiant temperature (MRT) is the area-weighted average of all the
surface temperatures in a room, and is affected by the position of the person in relation
to the various surfaces. The larger the surface area and the closer to the person, it will
have more influence to an occupant’s MRT. This explains why the roof plays an
important role in determining the overall MRT of the building, which will have a direct
8
impact on the thermal comfort level of the occupants. According to Peng Chen (2002),
the thermal radiation of roof largely depends on the composition materials.
Figure 2.1: Thermal radiation from roof into interior (Cowan, 1973)
The optimization of the thermal performance of the roof can be achieved through
different levels of thermal mass, insulation, geometry of ceiling, external colour and
levels of ventilation (attic), and roof materials (Madhumathi et al., 2014).
2.4.1 Roof Materials
The heat gain through the outer shell of the structural section of the building consists of
a total transmitted amounts of heat in the state of stability (which arise from differing
degrees air temperature inside and outside building) and the unstable situation (resulting
from variation of solar radiation falling on the roofs of the building density) and
complicated heat transfer process through the roof of having heat capacity (whose value
9
depends on both the amount of conductivity makes them part of the stored heat
(Thermal, specific heat and density of the components of the roof). (Jones, 1987).
Transmitted through it, where the vagaries of the degree of heat to the outer surface of
the roof section does not appear rapidly fluctuations .Similar to the degree of the inner
surface temperature of the roof section, which means that the construction materials of
which the outer roof section will increase of the value of the thermal resistance of the
roof itself and thus will increase the amount of delay time to the heat transfer through it,
which requires the use of air-conditioning equipment throughout the hours per day to
absorb the thermal loads on arrival and reduce the degree of air space temperature to that
level specified in advance, which means that the electric power consumption for the
purposes of running the air conditioning equipment is linked to the amount of heat
transmitted through the roof of the building, reduce that heat will lead to reduce the
period of operation of air conditioners and thus reduce the amount of electrical energy
consumed for air conditioning purposes.
Warm climatic conditions generally prevail in low altitude areas between 15°
north and south latitudes. A significant portion of the global population lives in this
region, notably countries in North and South America, Africa, India, Indonesia,
Malaysia, Thailand and the Philippines. In this region, the path of the sun generally goes
through high altitudes during the daytime, subjecting the roofs of dwellings to intense
sunlight. Unlike vertical surfaces such as walls, the roof is exposed to the sun throughout
the daytime round the year, significantly contributing to building heat gain (Madhumathi
et al., 2014).
The roofing should be tightly fixed and the material should insulate the building
from both excessive heat and humidity. Primary requirements for roofing: low thermal
capacity (to avoid heat build-up, which cannot be dissipated at night, since there is no
temperature drop); resistance to rain penetration, yet permeable enough to absorb
moisture and release it when the air is drier; resistance to fungus, insects, rodents and
solar radiation; good reflectivity (to reduce heat load and thermal movements);
resistance to temperature and moisture fluctuations; freedom from toxic materials
(especially if rainwater is collected from roofs).
10
Optimizing roof materials can play a vital role in lowering down the heat built up in both
air-conditioned spaces and naturally ventilated spaces. Also to achieve a better thermal
performance of the roofs, it is desirable to have a multi-layered roof comprising
materials of different thermo physical properties. It can be concluded that the most
important physical property of a roof is the thermal conductivity, which must be as low
as possible.
The common roofing systems and materials used in Malaysian residential
developments, clay tiles with double sided aluminum foil and plasterboard ceiling is able
to produce the optimum thermal performance in relation to Mean Radiant Temperature
(Allen et al., 2009). This is followed by concrete tile roofing system with double sided
aluminum foil and plasterboard ceiling, and lastly metal deck roofing system with
double sided aluminum foil, rockwool as insulation materials and plasterboard ceiling.
2.4.2 Roof colour
Colour of wall and roof surface has a significant effect to the indoor air temperature
(Givoni, 1994). Previous studies show that colour on the building envelope had a
significant impact to the indoor thermal condition. Many studies carried out works on
the effect of light colour on the building envelope to its indoor temperature. Bansal et at
(1992) argued that a room painted with white colour has lower indoor air temperature
than a room painted with black colour with about 6°C in summer and 4°C in winter.
Study by Cheng et al (2005) also indicated that building colour has significant effect on
the indoor air temperature. The study reported that dark colour had more than 10-degree
air temperature higher than white colour. The study also showed that the intensity of
solar radiation plays the vital role as the dark colour has more heat absorption due to
solar radiation. A study on passive solar cooling was conducted in arid climate by Amer
11
(2006), showes that indoor air temperature had about 6 °C lower than outdoor
temperature for the white colour painted roof (Bakhlah, M. S., Hassan, A. S.,2012).
A study on the effect of building colour to the outdoor and indoor surface
temperature was carried out by Givoni (1994), involving three types of roof thickness (7,
12 and 20 cm) and two different colours (grey and white). For grey colour with outdoor
air temperature of 31°C the average external surface temperature recorded was 69°C
whereas the indoor surface temperatures affected by the thickness (7, 12 and 20 cm) of
the roof were 45, 39 and 33°C respectively. For white colour with outdoor air
temperature of 27°C, the average external surface temperature recorded was 27.5°C,
while the indoor surface temperature for three different roof thicknesses were the same,
which was 25.5°C. The study also reported that the diurnal average of external surface
temperature of white colour was lower than the air temperature, which indicates that the
radiant loss is higher than energy absorbed in the white roof (Miller et al., 2000).
Akbary et al (1992) investigated the amount of energy savings on white colour
surfaces, the study showed that the roofs with white colour reduced the energy use of
air-conditioning by saving of 12kWh/day in electrical energy and 2.3 kW in peak power.
Roof and wall painted with white colour saved 50% of the electricity use in air
condition. Parker et al (1996) in their experimental study on residential building in
Florida found that 20% of electricity for air conditioning was reduced after applying
white reflective roof coatings. Sixty eight percent of solar radiation was reflected with
an acrylic white elastomeric coating with 63% after one-year age of coating. The study
showed that white roofing system had an improvement in indoor thermal comfort.
Parker et al (1997) studied the effect of white roof colour on cooling load on seven retail
shops. The result showed a saving of an average of 25.3% electricity in summer.
Rosangela (2002) found that the use of reflective white surface had the best
performance and reduced the need of insulation. This significant drop in the temperature
of upper air was due to the white tile concrete roof. Suehrcke et al (2008) summarized in
their literature study that the use of roof reflective surfaces materials such as white
colour had significant increase to the thermal comfort because of cooling loads
reduction.
12
According to Mohammed& Ahmad (2012), painting the roof with white colour, resulted
in reducing the indoor roof surface temperature, which in turn reduced the heat transfer
through the roof to the indoor. The reduction occurred in the amount of heat transmitted
through the roof, which means that painting the roof surface with white colour has
improved indoor thermal comfort. The highest indoor roof surface temperature before
painting occurred at night when the outdoor air temperature had dropped. It is possible
to control this heat gain by enhancing the air exchange between indoor and outdoor.
2.4.3 The angle of inclination in roof
Hasan (2008), mentioned that by increasing the angle of inclination of the roof the
amount of heat leaking from the roof of an apartment building can achieve greater
savings in electrical energy consumed. For the purpose of the annual air-conditioning
concrete roof inclined at an angle of 5 degrees from the horizon, the biggest saving
achieved was when the roof was the leaning towards the north where the amount of
energy savings of 11% per year, followed by facing towards the north-east and then
north-west a little difference, while avoiding routing towards south, east and west and
south to the negative impact.
According to Ali (2008), the maximum saving in electrical energy for
purpose cooling at inclined concrete ceiling by 5 at North orientation was 11% and then
north-east & north-west. The south, south-east and south-west orientation were
neglected, because their's opposite effects. Also, the researcher found that level clay
saving 55% from ordinary electrical energy, but it's very heavy on ceiling and increases
it's dead loads. While, the inclined steel structure with fired clay covered saved 48.2%
and become 38.4% when used reeds stalks sheaye 25mm thickness beside the
asbestoscenent by light class fiber.
The fact that the sunlight received by the building surfaces are larger than the
effect on the temperature of the environment (Shadow), the temperature change of the
internal space of the building, was influenced by the increase in the degree of inclination
13
of the roof . This affect more in reducing the energy required in conditioning the
building, while the effect of the surface of the building guide change (summer and
winter), since the change is a courier to note that. The rate of change in the external
boundary layer temperature of the roof of the building change in hourly manner per day
depending on how much sunshine that part of the roof was exposed (Kharrufa et al.,
2008).
Hasan (1984), mentioned that the angle of inclination roof of the building will
lead to reduced leakage annual warming over the roof of the building, thereby reducing
the amount of electrical energy required for air conditioning annually. Figure 2.2 shows
the angle of inclination in roof.
Figure 2.2: The angle of inclination in roof (Gartland &Turnbul, 2010).
14
2.4.4 Cool roofs
Cool roofs are roofs that are designed to maintain a lower roof temperature than
traditional roofs where exposed to the sun shine. Sunlight is the primary factor that
causes roofs to become very hot. Cool roofs have surfaces that reflect sunlight and emit
heat more efficiently than hot or dark roofs, keeping them cooler in the sun. In contrast,
hot roofs absorb much more solar energy than cool roofs, making them hotter. Solar
reflectance and thermal emittance are the two key material surface properties that
determine a roof’s temperature, and they each range on a scale from 0 to 1. The larger
these two values are, the cooler the roof will remain in the sun (Urban & Roth, 2010).
Figure 2.3 shows the effect of color on heat transmission and reflectance of roof.
Figure 2.3: Roof with conventional paint (a) and with cool roof paint (b) (Bryan &Kurt,
2010).
Since most dark roofs absorb 90% or more of the incoming solar energy, the roof
can reach temperatures higher than 150°F (66ºC) when it’s warm and sunny. Higher roof
temperatures increase the heat flow into the building, causing the air conditioning
system to work harder and use more energy in summertime. In contrast, light-colored
roofs absorb less than 50% of the solar energy, reducing the roof temperature and
decreasing air conditioning energy use.
15
The solar radiation that strikes a roof is comprised of a spectrum of energy levels.
Visible light is only a small part of the overall spectrum. The ultraviolet and infrared
radiation that hits a roof can be either reflected or absorbed. The fraction of incident
solar radiation that is reflected from the surface is the Total Solar Reflectance.
The absorbed energy converts to heat at the roof surface which can transfer into
the living space below or be released back to the night sky. The fraction of infrared heat
energy that a roof releases is known as infrared or thermal emittance. Any heat energy
can also be transferred from the roof surface to the ambient air by convection with air
movement. The changes in the reflectance and emittance properties due to weathering of
the roof are very important in the overall cooling and heating energy consumption of a
building over time (Hasan & Brown, 2013).
Cool roofing is gaining in popularity due to its ability to reduce cooling and
heating energy usage. Utility companies are also interested in cool roofing because it can
help reduce the peak demand in electricity during the afternoon hours of summer
months, preventing power disruptions. And, from an environmental point of view, cool
roofing can also help to mitigate a phenomenon known as the heat island effect (Kriner,
2006).
Cool roofing is described by two main terms: solar reflectance and thermal
emittance. Total solar reflectance (TSR) is the percentage of all solar radiation that is
immediately reflected from a surface. Any energy that is not reflected from a surface is
absorbed by the material. Some of this is transferred to heat which can be removed by
convective transfer from air flow over the surface. Some of the heat can be conducted
through the surface. More importantly, some of the heat can be re-emitted to the night
sky in the form of infrared wavelength energy. The latter phenomenon is known as
thermal emittance (TE). The combination of solar reflectance and thermal emittance
properties of a material determine the surface temperature of a roof and its ability to act
cool (Kriner, 2006).
16
2.5 Applications of air conditioning
Most air conditioning systems are used for either human comfort or for process contral.
From life experiences and feelings, we already know that air conditioning enhances our
comfort. Certain ranges of air temperature, humidity, cleanliness, and motion are
comfortable; others are not (Pita, E. G., 2002).
Human beings (Jones, 2001) are born into a hostile environment, but the degree
of hostility varies with the season of the year and with the geographical locality. This
suggests that the arguments for air conditioning might be based solely on climatic
considerations, but although these may be valid in tropical and subtropical areas, they
are not for temperate climates with industrialised social structures and rising standards
of living.
Briefly, air conditioning is necessary for the following reasons. Heat gains from
sunlight, electric lighting and business machines, in particular, may cause unpleasantly
high temperatures in rooms, unless windows are opened. Air conditioning is also used to
provide conditions that some processes require. For example, textile, printing, and
photographic processing facilities, as well as computer rooms and medical facilities,
require certain air temperatures and humidity for successful operation. The most
important applications of air conditioning (Pita, E. G., 2002) are as below:
Comfort air conditioning: Domestic, offices, shops cinema halls ,
hospitals, computer centers, libraries, restaurants, hotels, night clubs,
transportation, telephone exchanges, beauty saloons, radio and TV
stations, auditoriums, malls, museums, ships
Industrial air conditioning:
(a) Laboratories: to make precise measurements.
(b) To study the effect of temperature and moisture on living beings.
(c) Control of humidity in multi-color printing.
17
(d) Textile manufacture greatly depends on moisture control.
(e) Dry air is required in steel manufacture.
(f) Pharmaceutical industry needs refrigeration to reduce air borne bacteria.
(g) Photographic products deteriorate rapidly at high (temperatures, humidity).
(h) Farm animals: improves the quality and quantity of milk.
2.6 Insulation
Insulation is one of those ubiquitous techniques that is always around, always impinging
on our work, social and domestic activities and yet for most of the time is hardly
noticed. Insulation is a passive product; once installed, it works efficiently, quietly and
continually, usually out of sight, enclosed within a structure or a casing or under
cladding.
It comes to the fore when new design of buildings, plant, equipment or
production processes is being considered. It is at this stage that the right specification
must be made. Any shortfall in the thickness or error in the type and application details
will prove costly to rectify at a later date (Mobley, 2001).
18
2.6.1 Generic types of insulation
The type indicates composition (i.e. glass, plastic) and internal structure (i.e. cellular,
fibrous) (Best practices guide, 2011):
i. Fibrous Insulation - composed of small diameter fibers which finely divide the
air space. The fibers may be perpendicular or parallel to the surface being
insulated, and they may or may not be bonded together. Silica, rock wool, slag
wool and alumina silica fibers are used. The most widely used insulations of this
type are glass fiber and mineral wool. Glass fiber and mineral wool products
usually have their fibers bonded together with organic binders that supply the
limited structural integrity of the products.
ii. Cellular Insulation - composed of small individual cells separated from each
other. The cellular material may be glass or foamed plastic such as polystyrene
(closed cell), polyisocyanurate and elastomeric.
iii. Granular Insulation - composed of small nodules which may contain voids or
hollow spaces. It is not considered a true cellular material since gas can be
transferred between the individual spaces. This type may be produced as a loose
or pourable material, or combined with a binder and fibers or undergo a chemical
reaction to make a rigid insulation. Examples of these insulations are calcium
silicate, expanded vermiculite, perlite, cellulose, diatomaceous earth and
expanded polystyrene. Figure 2.4 shows generic types of insulation.
Figure 2.4: Granular insulation a, cellular insulation b and fibrous insulation c (Best
practices guide, 2011).
19
2.6.2 Generic forms of insulation
Insulations are produced in a variety of forms suitable for specific functions and
applications. The combined form and type of insulation determine its proper method of
installation. The forms most widely used are (Best practices guide, 2011):
a. Rigid boards, blocks, sheets, and pre-formed shapes such as pipe
insulation, curved segments, lagging etc. Cellular, granular, and fibrous
insulations are produced in these forms.
b. Flexible blankets. Fibrous insulations are produced in flexible blankets.
c. Cements (insulating and finishing). Produced from fibrous and granular
insulations and cement, they may be of the hydraulic setting or air drying
type.
d. Foams. Poured or froth foam used to fill irregular areas and voids. Spray
used for flat surfaces.
2.6.3 Thermal insulation
A thermal insulation (Mobley, 2001) material is one that slows down the rate of heat
loss from a hot surface and similarly reduces the rate of heat gain into a cold body. It
will not stop the loss or gain of heat completely.
No matter how well insulated, buildings will need a continual input of heat to
maintain desired temperature levels. The input required will be much smaller in a
wellinsulated building than in uninsulated ones – but it will still be needed. The same
applies to items of plant – pipes, vessels and tanks containing hot (or cold) fluids. If
20
there is no heat input to compensate for the loss through the insulation the temperature
of the fluid will fall. A wellinsulated vessel will maintain the heat of its contents for a
longer period of time but it will never, on its own, keep the temperature stable. Thermal
insulation does not generate heat. It is a common misconception that such insulation
automatically warms the building in which it is installed. If no heat is supplied to that
building it will remain cold. Any temperature rise that may occur will be the result of
better utilization of internal fortuitous or incidental heat gains.
2.6.4 Principles of insulation
2.6.4.1 Heat transfer
Before dealing with the principles of insulation, it is necessary to understand the
mechanism of heat transfer. When an area that is colder surrounds a hot surface, heat
will be transferred and the process will continue until both are at the same temperature.
Heat transfer takes place by one or more of three methods: conduction, convection and
radiation.
Conduction is the process by which heat flows by molecular transportation along
or through a material or from one material to another, the material receiving the heat
being in contact with that from which it receives it. Conduction takes place in solids,
liquids and gases and from one to another. The rate at which conduction occurs varies
considerably according to the substance and its state. In solids, metals are good
conductors – gold, silver and copper being among the best. The range continues
21
downwards through minerals such as concrete and masonry, to wood, and then to the
lowest conductors such as thermal insulating materials. Liquids are generally bad
conductors, but this is sometimes obscured by heat transfer taking place by convection.
Gases (e.g. air) are even worse conductors than liquids but again, they suffer from being
prone to convection (Mobley, 2001).
Convection occurs in liquids and gases. For any solid to lose or gain heat by
convection it must be in contact with the fluid. Convection cannot occur in a vacuum.
Convection results from a change in density in parts of the fluid, the density change
being brought about by an alteration in temperature. If a hot body is surrounded by
cooler air, heat is conducted to the air in immediate contact with the body. This air then
becomes less dense than the colder air further away. The warmer, light air is thus
displaced upwards and is replaced by colder, heavier air which, in turn, receives heat and
is similarly displaced. There is thus developed a continuous flow of air or convection
around the hot body removing heat from it. This process is similar but reversed if warm
air surrounds a colder body, the air becoming colder on transfer of the heat to the body
and displaced downwards.
The process by which heat is emitted from a body and transmitted across space
as energy is called radiation. Heat radiation is a form of wave energy in space similar to
radio and light waves. Radiation does not require any intermediate medium such as air
for its transfer. It can readily take place across a vacuum. All bodies emit radiant energy,
the rate of emission being governed by (Mobley, 2001):
The temperature difference between radiating and receiving surfaces.
The distance between the surfaces.
The emissivity of the surfaces. Dull surfaces are good emitters/receivers;
bright reflective surfaces are poor ones.
22
2.6.4.2 Requirements of an insulant
In order to perform effectively as an insulant a material must restrict heat flow by any
(and preferably) all three methods of heat transfer. Most insulating materials adequately
reduce conduction and convection elements by the cellular structure of the material. The
radiation component is decreased by absorption into the body of the insulant and is
further reduced by the application of bright foil outer facing to the product.
Mobley .R, (2001) stated that in order to reduce heat transfer by convection an
insulant should have a structure of a cellular nature or with a high void content. Small
cells or voids inhibit convection within them and are thus less prone to excite or agitate
neighboring cells. To reduce heat transfer by conduction, an insulant should have a small
ratio of solid volume to void. Additionally, a thin-wall matrix, a discontinuous matrix or
a matrix of elements with minimum point contacts are all beneficial in reducing
conducted heat flow. A reduction in the conduction across the voids can be achieved by
the use of inert gases rather than still air. Radiation transfer is largely eliminated when
an insulant is placed in close contact with a hot surface. Radiation may penetrate an
open-cell material but is rapidly absorbed within the immediate matrix and the energy
changed to conductive or convective heat flow. It is also inhibited by the use of bright
aluminum foil, either in the form of multi-corrugated sheets or as outer facing on
conventional insulants.
2.6.5 Insulation Product selection
In selecting an insulation product for a particular application, consideration should be
given not only to its primary function but also to the many secondary functions. Some
23
of these product requirements (Mobley, 2001) are:
i. Limiting temperatures:
Must ensure that the insulation selected can operate effectively and without
degradation at temperatures beyond the design temperature called for.
Temperature control of the process system can fail and systems can overheat.
Hot surfaces exposed to ambient air will become hotter when insulated if there is
no control of the process temperature. As with multi-layer systems, the addition
of an extra layer of insulation will change the interface temperatures of all inner
layers. Do not use an insulant close to a critical temperature limit.
ii. Thermal movement:
Large vessels and equipment operating at extreme temperatures exhibit large
expansion or contraction movements. Any insulant specified for these
applications should be capable of a sympathetic movement such that it will not
cause itself or any cladding to burst, nor should it produce gaps that lead to
dangerous hot spots in the cladding system.
iii. Mechanical strength:
Many insulants are made in a wide range of densities and thus mechanical
strengths. Ensure that where insulation is required to be load bearing, to carry
cladding, to support itself across gaps or drape down the sides of buildings
or high equipment, the selected product has the necessary strength to
accommodate these mechanical requirements as well as the primary thermal one.
iv. Robustness:
Insulation is subjected to abuse onsite, in storage and often in transit. To ensure
minimum wastage through breakage, contamination or deformation, select
products which are resilient or robust enough to tolerate site conditions and
malpractice.
v. Chemical resistance:
No matter how well installed, insulation is always at risk of contamination from
outside sources. Overfilling of vessels, leaking valves and flanges, oil thrown off
from rotating transmission shafts and motors can all penetrate protective
24
cladding or lining systems. Consideration of any insulation’s compatibility with
possible contaminants should be considered in these situations.
vi. Weather resistance:
Insulation applied to externally located equipment can be subjected to rain and
weather contamination if the outer cladding fails. Insulants with water-repellant,
water-tolerant or free-draining properties offer an additional benefit in this type
of application. In the structural field insulants used as cavity wall fills must
be of those types specially treated and designed for this application.
vii. Surface emissivity:
The effects of surface emissivity are exaggerated in high temperature
applications, and particular attention should be paid to the selection of the type of
surface of the insulation system. Low-emissivity surfaces such as bright polished
aluminum reduce heat loss by inhibiting the radiation of heat from the surface to
the surrounding ambient space. However, by holding back the heat being
transmitted through the insulation, a ‘dam’ effect is created and the surface
temperature rises. This temperature rise can be considerable, and if insulation is
being used to achieve a specified temperature the use of a low-emissivity system
could necessitate an increased thickness of insulation. For example, a hot surface
at 550°C insulated with a 50mm product of thermal conductivity 0.055 and
ambient temperature of 20°C would give a surface temperature of approximately
98°C, 78°C and 68°C when the outer surface is of low (polished aluminum),
medium (galvanized steel) or high (plain or matte) emissivity, respectively.
Conversely, to achieve a surface temperature of 55°C with the same conditions
the insulation would need to be approximately 120 mm, 87mm and 70 mm,
respectively.
viii. Acoustics:
Because of their cellular or open-matrix construction, most insulants have an
inherent ability to absorb sound, act as panel dampers and reduce noise breakout
from plant by their ability to be a flexible or discontinuous link between an
acoustically active surface and the outer cladding.
REFERENCES
1. ASHRAE. (2008). Handbook-HVAC Systems and Equipment (SI). Atlanta:
American Society of Heating, Refrigerating, and Air-conditioning Engineers,
Inc.
2. ASHRAE. (2005). Handbook of fundamentals. Atlanta: American Society of
Heating, Refrigerating, and Air-conditioning Engineers, Inc.
3. ASHRAE Special Project 102. (2004). Advanced energy design guide for small
office buildings. Atlanta: American Society of Heating, Refrigerating, and Air-
conditioning Engineers, Inc.
4. Al-Dabbagh, M. (2006). Cooling Load Calculations. Retrieved on May 2006,
from
http://faculty.uoh.edu.sa/m.mousa/Books/Air%20Cond%20Tech/Chapter%202%
20Air%20Cond%20Tech.pdf.
5. ALI, A. (2008). The Reduction of Heat Transfer for Concrete Ceiling In
Residence Building by Changing the Angle of Inclination. The Iraqi Journal For
Mechanical And Material Engineering, Special Issue (C), PP.484-498.
6. ALI, A. (2012). The Experimental Study For Heat Transferred From Building
Roofs and Roof Finishing System Usage. The Iraqi Journal For Mechanical And
Material Engineering, 12(1), PP.910-930.
86
7. Ali, SH. (2010). Analysis of procedures and workflow for conducting energy-
Analysis using Auto Desk Revit, GBXML and TRACE 700. Retrieved on
August 11 – 13, 2010, from
http://www.ibpsa.us/sites/default/files/publications/SB10-PPT-TS02A-02-
Ali.pdf.
8. ASHRAE. (2011). Handbook- Heating, ventilating, and air conditioning
Applications. SI Edition. Atlanta: American Society of Heating, Refrigerating,
and Air-conditioning Engineers, Inc.
9. ASHRAE. (2013). Handbook of fundamentals. Cooling Loads Calculations.
Retrieved on August 2013, from
http://www.4msa.com/WhitePapers/ASHRAE%20Example%20room%20-
%20Cooling%20loads.pdf.
10. Auto desk Inc. (2012). Building Design Suite 2013.USA: Trade brochure.
11. Bakhlah, M. S., Hassan, A. S. (2012). The Effect of Roof Colour on Indoor
House Temperature In Case of Hadhramout, Yemen. American Transactions on
Engineering & Applied Sciences, 1(4). (2229-1652), PP. 365-378.
12. Bali, S. P. (2005). Consumer Electronics. Pearson Education. Singapore: Pearson
Education (Singapore) pte. Ltd.
13. Best practices guide 02. (2011). Insulation materials and properties. Retrieved
from http://www.tiac.ca/downloads/best-practices-guide/BestPracticesGuide-
02_E.pdf.
14. Bhatia, A. (2012). HVAC Made Easy: A Guide to Heating & Cooling Load
Estimation. An Approved Continuing Education Provider. PP. 1-79.
15. D’Orazio, M., Di Perna, C. & Di Giuseppe, E. (2010). The effects of roof
covering on the thermal performance of highly insulated roofs in Mediterranean
climates. Energy and Buildings, 42 (2010), PP 1619–1627.
16. DOW. (2012). Roofing Applications. Retrieved from
http://building.dow.com/na/en/products/insulation/rigidfoam.htm.
17. Eicker, U. (2009). Low energy cooling for sustainable buildings. Stuttgart
University of Applied Sciences, Germany. Great Britain: John Wiley & Sons,
Ltd.
87
18. Gartland, L., Turnbul, P. (2010). Cool roof design brief. Retrieved from
http://www.pge.com/includes/docs/pdfs/shared/saveenergymoney/rebates/remod
eling/coolroof/coolroofdesignbrief.pdf.
19. Green restaurant. (2011). Polystyrene foam report. Retrieved from
http://www.earthresource.org/campaigns/capp/capp-styrofoam.html.
20. Haines, R. W. & Wilson, C. L. (1998). HVAC System Design- Handbook.3rd
ed.
USA: The McGraw-Hill Companies, Inc.
21. Harvey, L., D., D. (2006). Net climatic impact of solid foam insulation produced
with halocarbon and non-halocarbon blowing agents. Building and Environment,
42 (2007), PP 2860–2879.
22. Hasan, M., Karim, A. & Brown, R. (2013). Investigation of Energy Efficient
approaches for the energy performance improvement of commercial buildings.
Queensland University of Technology, Australia: Master of Engineering
(Research).
23. IBACOS, Inc. (2011). Strategy Guideline: Accurate Heating and Cooling Load
Calculations. USA: Office of Energy Efficiency and Renewable Energy U.S.
Department of Energy.
24. Jones, W.P. (2001). Air conditioning engineering. 5th ed. India: Elsever
Butterworth- Heinemann.
25. Jong, Jin, K. J. & Jin, W. M. (2009). Impact of Insulation on Building Energy
Consumption. Eleventh International IBPSA Conference, 2009, PP. 674-680.
26. Kharagpur, M. (2006). Cooling and Heating Load Calculations -Estimation of
Required Cooling/Heating Capacity. Retrieved on Sep 2006, from
http://nptel.ac.in/courses/112105129/pdf/R&AC%20Lecture%2035.pdf.
27. Kharrufa, S. , N., Ebraheem, A. Y., Jasim, A. N. (2008). Thermal Simulation of
Custom Designed House to Test Application of New Cooling Methods. Iraqi
Academic Scientific, 4B (14-15), PP 62-75.
28. Kharrufa, S., N. & Adil, Y. (2007). Roof pond cooling of buildings in hot arid
climates. Building and Environment, 43 (2008), PP 82–89.
29. Kolokotsa, D. (2013). Cool and Reflective Materials for the Built Environment.
Retrieved on July 2013, from
88
http://www.ijovent.org.uk/CIBSE_NVG_210613/Denia%20Kolokotsa%20Cool_
Reflective_Materials.pdf.
30. Kreith, F. (1998). The CRC Handbook of Mechanical Engineering. Second
Edition. USA: CRC press, lnc.
31. Kriner, S., (2006). Cool Metal Roofing – An Emerging Hot Topic. Retrieved
from
http://www.coolmetalroofing.org/elements/uploads/casestudies/tmi_casestudy_2
5.pdf.
32. Lollini, Barozzi, Fasano, Meroni & Zinzi. (2005). Optimisation of opaque
components of the building envelope Energy, economic and environmental
issues. Building and Environment, 41 (2006), PP 1001–1013.
33. Madhumathi, A., Radhakrishnan, S. & Priya, R., SH. (2014). Sustainable Roofs
for Warm Humid Climates -A Case Study in Residential Buildings in Madurai,
tamilnadu, India. World Applied Sciences, 32(6), PP. 1167-1180.
34. McQuiston, F. C., Parker, J. D. & Spitler, J. D. (2000). Heating, ventilating, and
air conditioning: analysis and design. 5th ed. India: John Wiley & Sons, Inc.
35. McQuiston, F. C., Parker, J. D. & Spitler, J. D. (2005). Heating, ventilating, and
air conditioning: analysis and design. 6th
ed. USA: John Wiley & Sons, Inc.
36. Miller, A. W., Parker, S. D. & Akbar, H. (2000). Painted Metal Roofs are
Energy-Efficient, Durable and Sustainable. Retrieved on July 26, 2000, from
http://www.coolmetalroofing.org/elements/uploads/casestudies/tmi_casestudy_2
7.pdf.
37. Mobley, R. K. (2001). Plant engineer’s handbook. Rev. ed. The United States of
America: Butterworth-Heinemann.
38. Pita, E. G. (2002). Air conditioning principles and systems. 4th ed. New Jersey:
Pearson Education, Inc.
39. Plastic Europe, lnc. (2012). Building our future. Sustainable Insulation with
Polystyrene Foam. Retrieved from http://www.jackon-
insulation.com/uploads/tx_wwdownloads/PlasticEU_Polystyrene_Foam_Brochu
re_Okt_2012_b.pdf.
89
40. Roodvoets, D., Miller, W. A & Desjariais, A. O. (2004). Saving Energy by
Cleaning Reflective Thermoplastic Low-Slope Roofs. Retrieved on December
2004, form http://web.ornl.gov/sci/roofs+walls/staff/papers/new_51.pdf.
41. SAPALI, S. N. (2009). Refrigeration and Air Conditioning. New Delhi: PHI
Learning private Limited.
42. Stephan, E., Cantin, R., Caucheteux, A., Guemouti, S. T. & Michel, P. (2014).
Experimental assessment of thermal inertia in insulated and non-insulated old
limestone buildings. Building and Environment, 80(2014), PP. 241-248.
43. Stine, d. j. (2011). Design integration using Autodesk Revit 2012.USA: Auto
desk Inc.
44. Toguyeni, D. Y. K., Coulibaly, O., Ouedraogo, A., Koulidiati, J., Dutil, Y. &
Rousse, D. (2012). Study of the influence of roof insulation involving local
materials on cooling loads of houses built of clay and straw. Energy and
Buildings, 50 (2012), PP 74–80.
45. Tongshoob, T. & Vitooraporn, CH. (2005). A Probabilistic Approach for
Cooling Load Calculation. ASHRAE Thailand Chapter,9(3), pp. 29-34.
46. Trott, A. R. & Welch T. (2000). Refrigeration and Air-Conditioning. Third
edition. New Delhi: Butterworth-Heinemann.
47. Urban, B. & Roth, K. (2010). Guidelines for Selecting Cool Roofs. Retrieved on
July 2010, from http://www1.eere.energy.gov/femp/pdfs/coolroofguide.pdf.
48. Wang, SH. K. (2000). Handbook of air conditioning and refrigeration. 2nd ed.
USA. The McGraw-Hill Companies, Inc.
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