The Journal of Engineering Research (TJER), Vol. 18, No. 2, (2021) 82-90 
 

 
      

*Corresponding author’s e-mail: raa37@kent.ac.uk 
   
 
  DOI:10.53540/tjer.vol18iss2pp82-90 

 A COMPARISON STUDY BETWEEN THE THERMAL PERFORMANCE OF 
THE ORIGINAL AND REBUILT VERNACULAR BUILDINGS OF DANA 

VILLAGE IN JORDAN  
 

 Rawan Allouzi*, Nikolaos Karydis, and Marialena Nikolopoulou  
School of Architecture and Planning, University of Kent, Canterbury, United Kingdom 

 
 

ABSTRACT: The settlement of Dana in Jordan is undergoing dramatic and rapid changes. The rehabilitation 
project launched by the Royal Society for the Conservation of Nature (RSCN) provided new tourist 
accommodation within the settlement, in a way that preserves its unique vernacular character. This has involved 
the repair and transformation of existing dwellings as well as the rebuilding of those that have been demolished. 
Currently, the original and rebuilt buildings stand side by side, offering a unique opportunity to compare their 
thermal performance. This comparison is essential to understand the impact of new construction materials and 
opening sizes on the thermal performance of vernacular buildings. For this purpose, the thermal performance of 
rebuilt and original buildings was monitored in August 2019 and February 2020, representing the hot and cold 
seasons. The recorded data was interpreted statistically, aiming mainly to compare the results from the original 
rooms with those from the rebuilt rooms. The study showed that the original buildings of Dana hotel resist thermal 
transfer more than the rebuilt ones. Both parts provided thermal comfort in summer, with the rebuilt rooms offering 
slightly better thermal comfort conditions. However, neither original nor rebuilt rooms provided adequate thermal 
comfort in winter. 
 

 

Keywords: Dana village; Original buildings; Rebuilt buildings; Thermal comfort; Thermal performance; 
Vernacular settlement. 
 

 
 دراسة مقارنة بین األداء الحراري لمباني تراثیة أصلیة، وأخرى معاد بناؤھا في قریة ضانا في األردن

 
 ، نیكوالس كاریدیس، ماریالینا نیكولوبولو*روان اللوزي 

 
 

الذي أطلقتھ الجمعیة الملكیة  -وفر مشروع إعادة التأھیل تمر قریة ضانا في األردن بتغیرات دراماتیكیة وسریعة.  :الملخص
أماكن إقامة سیاحیة جدیدة في القریة بطریقة تحافظ على طابعھا المحلي الفرید، كما اشتمل على ترمیم  –للحفاظ على البیئة 

ؤه جنبا إلى جنب في الوقت الحالي، وتحویل المساكن القائمة، وإعادة بناء المنازل المتھدمة. تتواجد المباني األصلیة والمعاد بنا
مما یوفر فرصة فریدة لمقارنة أدائھا الحراري، وھي مقارنة ضروریة لفھم تأثیر مواد البناء الجدیدة وقیاسات الفتحات على 

أغسطس  األداء الحراري للمباني التقلیدیة، ولھذا الغرض، فقد تمت مراقبة األداء الحراري للمباني األصلیة والمعاد بناؤھا في
، باعتبارھم ممثلین للمواسم الحارة والباردة. على نحو أساسي بھدف مقارنة النتائج من الغرف األصلیة 2020وفبرایر  2019

وتلك المعاد بناؤھا، فقد تمت معالجة البیانات المسجلة احصائیا. أظھرت الدراسة أن المباني األصلیة لفندق ضانا تقاوم انتقال 
المعاد بناؤھا، كما یوفر كال النوعین من المباني الراحة الحراریة في فصل الصیف، مع مالحظة أن  الحرارة أكثر من تلك

الغرف المعاد بناؤھا توفر بشكل طفیف مستوى أعلى من األحوال الحراریة المریحة، وبالرغم من ذلك فال توفر الغرف 
 فصل الشتاء. األصلیة أو المعاد بناؤھا مستوى مناسب من الراحة الحراریة خالل

 

.قریة ضانا ؛قریة تقلیدیة ؛الراحة الحراریة ؛المباني المعاد بناؤھا ؛المباني األصلیة ؛األداء الحراري الكلمات المفتاحیة:



A Comparison Study between the Thermal Performance of the Original and Rebuilt Vernacular Buildings of 
Dana Village in Jordan 

83 

NOMENCLATURE 
 
R-value: Thermal resistance (m2.K/W) 
Tair: Air temperature (°C) 
Tout: Outdoor temperature (°C) 
U-value: Thermal transmittance (W/m2.K) 
 
1. INTRODUCTION 
 
Dana village (30.67° N, 35.61° E) in Jordan was built 
between the 1890s and 1930s. Dana was formed of 
single-story buildings with flat roofs. The organization 
of contiguous buildings in clusters is one of the main 
characteristics of the village, looking like one 
cohesive/compact unit. After the 1960s, the local 
community of Dana started to move out, looking for 
better services and job opportunities. By 1996, the 
village was almost abandoned, and most of its 
buildings turned into ruins (Figure 1). Therefore, the 
RSCN launched the rehabilitation project of Dana 
village in 2009 to restore vernacular dwellings to 
accommodate tourists and visitors (Al Haija, 2011). 

Several restoration strategies were implemented, 
such as the replacement of the original materials, the 
transformation of the building envelope, the 
enlargement of the opening sizes, and the addition of 
lighting shafts, and bathrooms (Table 1). The 
implementation of these changes affected the indoor 
thermal conditions that depend mainly on several 
factors, including the construction materials, opening 
sizes, thermal mass, and orientation (Alzoubi & 
Almalkawi, 2019; Fernandes et al., 2015; Meier et al., 
2004).  

Various previous studies discussed the effect of 
these factors on an individual basis, comparing the 
thermal performance of traditional and contemporary 
buildings. For instance, Tawayha et al. (2019) stated 
that using local and natural materials used in 
vernacular architecture plays an essential role in 
improving thermal performance. Weber & Yannas 
(2013) and Priya et al. (2012) added that the 
advantages of using local construction materials in 
improving the thermal performance of vernacular 
buildings include the low conductivity of thermal 
transfer and providing stable indoor thermal 
conditions. Furthermore, Toe & Kubota (2015) and 
Philokyprou & Michael (2012) stated that the high 
thermal mass improves the indoor temperature 
stability, reduces daily fluctuation, and increases the 
time lag. Indeed, having thicker walls with higher 
thermal mass adapts vernacular buildings to the hot 
conditions by reducing exposure to direct solar 
radiation. Whereas in winter, the small size of openings 
provides thermal comfort as it allows the direct solar 
gains and protects the indoor spaces from cold and 
strong winds (Tawayha et al., 2019). Previously 
conducted studies presented the impact of transforming 
the building’s envelope on an individual basis, 
including the construction materials, thermal mass, and 
opening sizes and orientation (Weber & Yannas, 2013; 

Fernandes et al., 2015; Alzoubi & Almalkawi, 2019). 
However, there is a shortage in the study of the total 
impact of the restoration strategies of vernacular 
buildings as most studies focused on comparing 
vernacular and contemporary buildings. Therefore, this 
paper seeks to assess the effectiveness of the 
restoration strategies of Dana village by analyzing the 
thermal performance of both the original and rebuilt 
vernacular buildings. It aims to identify which type is 
more effective in providing thermal comfort in summer 
and winter while highlighting the effect of the 
restoration on thermal performance. For this purpose, 
the internal and external conditions of Dana hotel were 
monitored in August 2019 and February 2020 as 
representative of the hot and cold season. Dana has a 
cold climate in winter and a temperate to warm climate 
in summer (Table 2). 
 

 
 
Figure 1. Figure Ground Plan of Dana Village (top), Dana 

village before (middle) and after abandonment 
(bottom) (Archive, RSCN, 2019). 

 
 
Table 1. The original and rebuilt elements of Dana village. 

 



Rawan Allouzi, Nikolaos Karydis, and Marialena Nikolopoulou  

84 
 

Table 2. Dana monthly air temperature (CLIMATE-DATA.ORG. Retrieved June,21,2020). 
Tair(°C) Jan Feb Mar Apr May June July Aug Sep Oct Nov Dec 

Avg 5.6 6.6 9.6 13.2 16.5 19.6 21.1 21.7 19.4 16.7 11.7 7.4 
Min 1.5 1.8 4.3 7.4 10.2 12.6 14.6 15.2 12.7 10.4 6.5 2.7 
Max 9.8 11.4 14.9 19.1 22.9 26.7 27.7 28.3 26.2 23 17 12.2 

 
Table 3. Thermal properties of the original and new materials (Alzoubi & Almalkawi, 2019, adapted by the author, 2020) 

 Original part  Rebuilt part 
M

at
er

ia
ls

 

T
hi

ck
ne

ss
 (c

m
) 

T
he

rm
al

 
co

nd
uc

ti
vi

ty
 

(W
/m

 K
) 

R
-v

al
ue

  
(m

2 .K
/W

) 

U
-v

al
ue

  
(W

/m
2 .K

) 

M
at

er
ia

ls
 

T
hi

ck
ne

ss
 (c

m
) 

T
he

rm
al

 
co

nd
uc

ti
vi

ty
 

(W
/m

 K
) 

R
-v

al
ue

  
(m

2 .K
/W

) 

U
-v

al
ue

  
(W

/m
2 .K

) 

E
xt

er
io

r W
al

l Stone 70 5 0.14 

1.
30

7 

Stone 20 5 0.040 

3.
35

6 

A mixture of clay 
and straw 10 0.16 0.625 

Concrete 10 1.7 0.059 
Hollow concrete 

block 15 0.833 0.180 

Cement plaster 2.5 1.3 0.019 

G
ro

un
d 

Fl
oo

r 

Earth 50 1.4 0.357 
0.

36
7 

Earth 50 1.4 0.357 

1.
09

6 

Gravel jeer 45 0.38 1.184 Base-course stone 15 1.5 0.10 

Base course stone 10 1.51 0.066 
Asphalt insulation 5 1.2 0.042 

Reinforced concrete 10 1.28 0.078 
Sand 45 0.42 1.071 Sand 10 0.40 0.25 

Cement mortar 2.5 0.931 0.027 Cement mortar 2.5 0.39 0.064 
Terrazzo tile 2.5 1.2 0.021 Terrazzo tile 2.5 1.20 0.021 

R
oo

f 

Juniper wood 5 0.17 0.294 

0.
48

1 

Cement mortar 2.5 0.93 0.027 

3.
25

7 Cane 3 0.056 0.536 Concrete 15 1.7 0.088 

A mixture of clay 
and straw 20 0.16 1.25 

Asphalt insulation 2 1.2 0.017 
Reinforced concrete 20 1.28 0.156 

Cement plaster 2.5 1.3 0.019 

2. DANA HOTEL 

Dana hotel, established in the late 1980s, was selected 
as a representative case study of Dana village as it 
consists of both original and rebuilt rooms. The original 
part of Dana hotel is formed of 12 single-story rooms, 
surrounding the central courtyard from three sides. It is 
built mainly of stone, juniper wood, cane, and a mixture 
of clay and straw. On the other hand, the rebuilt part of 
Dana hotel is formed of 6 en-suite hotel rooms 
composed of a bedroom, bathroom, lighting shaft, and 
kitchenette (Figure 2). It is built mainly of stone, 
concrete, hollow concrete block, and cement mortar. 
The use of new construction materials led to having 
different thermal properties between the original and 
new building envelope. The thermal properties of both 
building envelopes are shown in Table 3. The calculated 
U-Values highlighted that the building envelope of the 
original part of Dana hotel resists thermal transfer more 
than the rebuilt part. 
  
3. METHODOLOGY 
 
To practically assess the thermal performance of Dana 
hotel, 10 rooms were monitored for two months in Au 
gust 2019 and January 2020, including 6 original 
rooms and4 rebuilt rooms (Figure 2).  

 

 
Figure 2. The original and rebuilt part of Dana hotel with 

logger positions (Archive, RSCN, 2019). 
 

Tinytag loggers were used to record air temperature 
and relative humidity every 15 minutes, placed at 1.5 
m above the floor level. The collected data was 
analyzed and compared between the original and 
rebuilt rooms, demonstrating the variation of the 
indoor temperatures throughout the day and providing 
thermal comfort as the criteria of assessment of this 
study.  



A Comparison Study between the Thermal Performance of the Original and Rebuilt Vernacular Buildings of 
Dana Village in Jordan 

85 

These criteria of assessment were first analyzed 
within the original and rebuilt part of Dana hotel 
separately. The statistical method was used to analyze 
the monitored physical variables to assess the thermal 
performance. It illustrated the fluctuation of the 
recorded data (air temperature) throughout the day, 
from day to day, and from room to room. In addition, 
thermal comfort was investigated through the adaptive 
thermal comfort standards BSEN15251 (Nicol et al., 
2012). Then, a comparison study was conducted 
between the final results of both parts, using it as an 
evaluation method to assess the transformation of 
Dana’s original vernacular buildings within the 
thermal context. 
 
4. RESULTS 
4.1. Thermal Environment 
4.1.1.  Air temperatures in the original rooms 
The mean indoor temperature of the original spaces 
was always higher than the mean outdoor temperature 
in summer and winter (Table 4). A typical week of the 
fluctuation of air temperatures in the different spaces 
in the different seasons is illustrated in Figure 3. In 
summer, indoor temperatures followed the outdoor 
temperature profile but with a significant time lag. 
More specifically, the indoor temperature was low at 
night, dropping in the early morning to the minimum 
and then rising rapidly until the afternoon, when 
reaching the maximum temperature. However, the 
maximum temperature was always less than the 
outdoor temperature around noon due to the thermal 
mass in all spaces except in the kitchen (space #6), 
which is assumed to be from the high internal heat 
gains from cooking. The high thermal mass of the 
original masonry thick walls decreased heat transfer to 
indoor spaces, preventing heat from reaching indoors 
in the afternoon, which is the hottest part of the day, 
reaching 36°C. The high thermal mass demonstrates a 
thermal lag of 14 hours. Therefore, the night-time 
temperature difference between indoor and outdoor, 
which sometimes approaches 10°C, was more than 
during the day. Furthermore, the daily variation was 
noticeable in some spaces more than others due to 
different functions and occupancy times. Small 
variation and less significant fluctuation over the day 
were noticed in rooms #1, #3, #4, and #5. This is 
because the thermal inertia of the thick stone walls and 
clay roofs offered small fluctuations in the indoor 
temperature. The high thermal inertia of the original 
materials increased their capacity to store heat and then 
emitted it outdoors when the temperature is lower 
while a small percentage was emitted indoors. 

However, lower indoor temperatures were noticed in 
rooms #4 and #5 because their roof is not exposed to 
the outdoor conditions, having an additional floor at 
their side. Meanwhile, the roof of rooms #1 and #3 is 
exposed to outdoor conditions and solar radiation, 
leading to absorbed heat being transferred to indoor 
spaces. 

On the other hand, the diurnal swing values at 
rooms #2 and #6 were more significant and variable, 
ranging from 4°C to 9.7°C. For room #6, being used as 
a kitchen explained the excessive indoor temperature 
that rose above the outdoor temperature most of the 
time due to cooking’s produced heat. Therefore, the 
kitchen showed the same fluctuation and temperatures 
of rooms #4 and #5 when it was out of service for 
maintenance. Furthermore, the absence of windows 
also raised the indoor temperature, storing the heat 
indoors without efficient airflow and ventilation. 
Whereas for room #2, it was observed that its roof was 
replaced with a concrete one. Having its roof 
transformed among the other original spaces created a 
difference in the thermal performance. The new 
concrete roof failed to resist heat transfer due to its 
lower capacity to resist heat transfer than the original 
clay roofs. Therefore, the indoor temperature of room 
#2 showed more fluctuation, reaching higher points 
compared with the other original hotel rooms. 

A different pattern of variations was noticed in 
winter with lower temperatures. The indoor 
temperature followed the profile of the outdoor 
temperature in room #3, being the coldest room among 
the other original rooms. Its indoor temperature was 
either lower than the warm outdoor conditions or close 
to the cold outdoor conditions. Specifically, the indoor 
temperature did not increase with higher outdoor 
temperature but decreased with lower outdoor 
temperature. This is because the sun does not enter this 
room due to the absence of windows. Moreover, it 
showed less variation in temperatures as it was 
observed that it was not occupied during the winter 
monitoring period, and the hotel operators confirmed 
that.  Similarly, rooms #6 and #4 were also unoccupied 
but showed higher temperatures due to reduced heat 
losses from their roof, which is not exposed to the cold 
outdoor conditions. Room #1 had similar thermal 
behaviour to room #3 until it started being occupied as 
it is assumed that higher fluctuation appears during 
occupation due to the internal heat gains from 
occupants. It showed warmer conditions in the 
morning due to the eastern window that brings the 
sunrays indoors. However, still have small values of 
diurnal swing that vary from 0.1°C to 3°C. 

 
Table 4. Indoor air temperatures (°C) in the original rooms. 

 Tout Room #1 Room #2 Room #3 Room #4 Room #5 Room #6 
Jan Aug Jan Aug Jan Aug Jan Aug Jan Aug Jan Aug Jan Aug 

Mean 6.1 24.7 7.6 26 9.7 26.6 5.6 27 7.9 24.9 6.1 24.8 7.7 27.5 
Min. -0.9 16.3 4 23.4 5.4 22.6 2.1 24.6 6.7 21.9 2.4 21.7 5.6 23.3 
Max. 20.4 36.5 11.5 29.2 16.8 33.8 9.7 29.8 9.8 27.2 10.2 27.2 10.3 35 



A Comparison Study between the Thermal Performance of the Original and Rebuilt Vernacular Buildings of 
Dana Village in Jordan   

86  

 
 
Figure 3. Variation of indoor air temperature in the original 

rooms in a typical week in summer (top) and 
winter (bottom). 

 
 
Figure 4. Variation of indoor air temperature in the rebuilt 

rooms in a typical week in summer (top) and 
winter (bottom). 

On the other hand, the daily variation was more 
noticeable in room #2, with diurnal swing ranging 
between 2.4°C and 8°C. The indoor temperature was, 
most of the time, higher than the outdoor temperature 
The difference between the outdoor and indoor 
temperature sometimes approached 12°C when the 
outdoor temperature was cold, reaching -0.9°C. The 
indoor temperature reached its maximum in the 
afternoon and minimum at midnight. This is because 
when the outdoor temperature reached its maximum 
near noon, the concrete roof of room #2 transferred the 
absorbed heat to the indoor space after a short time due 
to its lower thermal capacity. As expected, the variation 
of indoor temperature was influenced by the building 
envelope and opening sizes and orientation, as well as 
construction materials. The few and small size of 
windows protected the indoor spaces from direct sun 
rays during summer days and offered good ventilation 
and cooling at night. Meanwhile, these windows 
allowed solar gain to indoor spaces during winter days 
due to their lower elevation angle. 

4.1.2.  Air temperatures in the rebuilt rooms 
The mean indoor temperature of the rebuilt spaces was 
close to the average outdoor temperature in summer, 
while it was always higher in winter (Table 5). A 
typical week of the fluctuation of air temperatures in 
the different spaces in the different seasons is 
illustrated in Figure 4. In summer, the trend of the 
indoor and outdoor temperature was different than the 
original rooms as the changes in the indoor temperature 
did not follow the changes in the outdoor temperature. 
Specifically, the indoor temperature was higher than 
the outdoor temperature at night and lower during the 
day. The fluctuation of the indoor temperature was 
small, and the temperature was consistent. Indeed, the 
daily variation was not noticeable in all spaces despite 

different occupancy hours as it was observed that 
tourists spent their daytime touring the village and its 
neighbouring areas. They reached the maximum 
temperature in the afternoon and the minimum in the 
morning. They provided cooler indoor temperatures 
when it was the warmest outside and warmer indoor 
conditions when it was the coldest outside.  

The enlargement of windows and the addition of 
lighting shafts helped in providing cooler conditions. 
In terms of enlarging the external windows, these 
windows enhanced air movement due to their bigger 
size. This strategy was efficient as they are northern 
windows, which do not bring in solar gains. Moreover, 
the addition of lighting shafts provided internal 
windows that enhanced the air movement and 
ventilation for cooling. Although room #7 does not 
have a lighting shaft, it provided cool conditions due to 
having three windows compared with one window in 
the other rooms. It was also observed that room #8 had 
slightly colder conditions compared with room #9 and 
room #10, although they have the same building 
envelope, opening size, and orientation. This is 
because room #8 is bigger, increasing the heat transfer 
area in the room. Moreover, room #7 and room #8 have 
approximately the same area, but room #7 was slightly 
warmer due to having southwestern windows that bring 
in solar gains, warming up the indoor spaces in the 
afternoon. 

 
Table 5. Indoor air temperatures (°C) in the rebuilt rooms. 

 Tout Room 
#7 

Room 
#8 

Room 
#9 

Room 
#10 

Jan Aug Jan Aug Jan Aug Jan Aug Jan Aug 
Mean 6.1 24.7 7.1 25.2 9.4 24.2 8.8 25.8 7.4 26.3 
Min. -0.9 16.3 4.5 23.6 6.9 22.5 5.9 23 4.2 23.6 
Max. 20.4 36.5 9.9 27.1 13.7 26 16.5 28.3 17 29.7 



A Comparison Study between the Thermal Performance of the Original and Rebuilt Vernacular Buildings of 
Dana Village in Jordan 

87 

 
A different pattern was noticed in winter with wider 

fluctuation, less affected by the changes of the outdoor 
temperature. Overall, the indoor temperature was 
higher than the outdoor temperature most of the time. 
Moreover, the daily variation was noticeable 
sometimes in some spaces more than others. For 
instance, the diurnal swing varied from 0.1°C to 8.7°C, 
showing small values at room #7 due to non-occupancy 
status. Meanwhile, the diurnal swing values at rooms 
#8, #9, and #10 were bigger and more variable 
according to their occupancy time.  
 

4.1.3. Comparison between temperatures in the 
original and rebuilt rooms 
The pattern of the indoor temperature variation was 
different in the original and rebuilt rooms of Dana 
hotel. In the summer, indoor temperatures were higher 
in the original rooms compared with the rebuilt rooms. 
The indoor temperature was more steady in the rebuilt 
rooms, showing less variation. On the other hand, the 
original spaces performed differently, as some spaces 
such as #2 and #6 showed more variation compared 
with the other original spaces. The more extreme 
values were noticed in the original spaces. However, 
they were closer to the mean value in the rebuilt spaces. 
In winter, the indoor temperatures were either similar 
in both properties and slightly warmer in the rebuilt 
rooms. Moreover, the original spaces showed different 
performance as some rooms such as #4 and #6 show 
less variation in the indoor temperature compared with 
the other original spaces as they were unoccupied at 
that time. Meanwhile, the other original and rebuilt 
spaces provided almost the same variations in the 
indoor temperature (Figure 5).  

The analysis highlighted that performance is 
greatly affected by the materials of the building 
envelope, opening sizes and orientation. The external 
walls of the original rooms are thicker with higher 
thermal storage compared to the walls of the rebuilt 
rooms, improving the resistance to heat gain in summer 
and heat loss in winter. Moreover, the original rooms 
of Dana hotel have small openings to reduce the 
climatic influence on the indoor thermal conditions. 
Along with the thick walls, they prevent solar gains in 
summer, limit the heat gains and losses, and benefit 
from night ventilation and wind breeze to cool down 
indoor spaces. Meanwhile, it reduces heat loss and 
allows solar gains in winter Figure 6). 

On the other hand, the addition of lighting shafts 
and the enlargement of northern windows adapt the 
rebuilt rooms to the outdoor conditions in summer. 
Bigger and more windows were used in the rebuilt 
rooms, enhancing air movement while preventing solar 
gains. The orientation of these openings reduced the 
impact of their size because the direct solar gain is the 
main contributor affecting the indoor temperature. 
Therefore, the inward and northern orientation of the 
windows and lighting shafts of the rebuilt rooms reduce 
the impact of being more exposed in summer. 

Moreover, passive cooling strategies, such as plants 
and trees in front of the rebuilt rooms, enhance night 
cool breezes. The adopted changes in the rebuilt rooms 
worked together to adapt to Dana’s weather as a whole 
system, including the replacement of the building 
envelope, the addition of lighting shafts, and the 
enlargement of northern windows. Replacing the 
building envelope without increasing the opening sizes 
would disable the whole system, as observed in room 
#2. The replacement of the original roof while keeping 
the original opening sizes failed to adapt to the outdoor 
conditions, providing more variation in the indoor 
temperatures. 
 

 
 
Figure 5. Box plot that shows the mean, extreme, and 

outlier values of indoor air temperature at each 
space in the original and rebuilt part of the hotel 
in summer (top) and winter (bottom). 

 
 

 
 
Figure 6. The role of the small size of windows in allowing 

solar gains in winter and preventing summer’s 
ones. 



A Comparison Study between the Thermal Performance of the Original and Rebuilt Vernacular Buildings of 
Dana Village in Jordan   

88  

4.2. Thermal Comfort 
4.2.1. Thermal comfort in the original rooms 
In summer, the daily mean indoor temperatures were 
entirely within the calculated ranges of comfort 
temperatures. The large area of the central courtyard 
plays a significant role in enhancing the efficiency of 
the original rooms in providing thermal comfort. The 
courtyard cools down the indoor temperature in 
summer as it is shaded by the surrounding walls, 
preventing the sunrays from warming up the rooms. 
Moreover, the addition of plants, pergolas, and trees 
also helps provide shading and cooling by evaporation 
from the plants’ green leaves. Overall, 100% of the 
mean indoor temperature lay within the comfort 
ranges; most daily mean indoor temperatures lay 
within the comfort range of category Ι, while others lay 
within the other two categories. Thus, desired thermal 
comfort was achieved in the original rooms in summer. 
In winter, however, 100% of the daily mean indoor 
temperatures lay outside the three categories of 
comfort, showing that the daily mean indoor 
temperature was significantly below comfort 
temperatures, suggesting that occupants would be in 
cold discomfort. Thus, all the original rooms showed 
failure in providing thermal comfort in winter Figure 
7). 

4.2.2.  Thermal comfort in the rebuilt rooms 
In summer, 100% of the mean indoor temperature lay 
within the comfort ranges; most daily mean indoor 
temperatures lay within the comfort range of category 
Ι, while others lay within category ΙΙ. Thus, thermal 
comfort was achieved in the rebuilt rooms in summer. 
In winter, 100% of the daily mean indoor temperatures 
also lay outside the three categories of comfort, 
suggesting that occupants would be in cold discomfort. 
Thus, all the rebuilt rooms showed a failure to provide 
thermal comfort in winter Figure 8).  

4.2.3. Comparison between thermal comfort at the 
original and rebuilt rooms 

Starting with the summer, both the original and rebuilt 
rooms provided thermal comfort. However, the rebuilt 
rooms offered slightly better thermal comfort avoiding 
the higher indoor temperatures. In addition to the 
passive cooling strategies discussed in both the original 
and rebuilt rooms, the urban pattern of Dana village 
played an essential role in providing thermal comfort, 
showing how the original occupants adapted their 
houses to the climatic conditions (warm summer and 
cold winter). The original houses were attached, 
sharing partition walls. This layout is useful in regions 
with hot and cold climatic conditions, as it minimizes 
the exposure of the building envelope to the outdoor 
environment, which consequently reduces heat transfer 
(Bodach et al., 2014; Philokyprou et al., 2017).  

This urban pattern also features open spaces, 
including streets and private courtyards that are well 
relatively small and well-enclosed. In this 
arrangement, the external walls are less exposed to the 
outdoor climatic conditions, increasing the building 

envelope’s thermal insulation. 

 
 
Figure 7. Scatter diagram of the mean indoor temperature 

within the comfort temperature ranges for the 
original rooms in summer (top) and winter 
(bottom). 

 

 
 
Figure 8. Scatter diagram of the mean indoor temperature 

within the comfort temperature ranges for the 
rebuilt rooms in summer (top) and winter 
(bottom). 



A Comparison Study between the Thermal Performance of the Original and Rebuilt Vernacular Buildings of 
Dana Village in Jordan 

89 

 
Table 6. The results of comparing the thermal conditions of the original and rebuilt rooms in summer and winter. 

 
Summer Winter 

Original Rebuilt Original Rebuilt 
Temperature Higher Temperature Lower Temperature Almost the Same Almost the Same 
Diurnal Swing Higher Lower Almost the Same Almost the Same 
Decrement Value Higher Lower Almost the Same Almost the Same 

Thermal Comfort Provide Thermal Comfort 
Provide Slightly Better 

Thermal Comfort 
Do not Provide 

Thermal Comfort 
Do not Provide 

Thermal Comfort 
 
Philokyprou et al. (2013) stated that due to narrow 

streets and spaces between houses, the neighbouring 
houses shade each other and reduce the heat gain 
through walls by radiation. On the other hand, both the 
original and rebuilt rooms did not provide thermal 
comfort in winter. Indeed, their daily mean indoor 
temperatures were very low, lying entirely outside the 
comfort ranges. The analysis of the thermal 
performance of the original and rebuilt rooms showed 
that the RSCN was more concerned about providing 
thermal comfort in the summer months because Dana 
is a summer tourist destination. Focus on the summer 
is also because winters in the region are normally 
shorter than summers. 
 
5. DISCUSSION AND CONCLUSION 
 
The thermal performance of the vernacular buildings 
of Dana demonstrated that the passive and heavy-
weight buildings, free-running with no heating or 
cooling systems, can provide thermal comfort during 
the summer. Singh et al. (2010), Abdel Hadi (2013), 
Philokyprou et al. (2013), Weber & Yannas (2013), 
and Tawayha et al. (2019) demonstrated that the 
thermal performance of vernacular buildings is 
generally better than contemporary buildings due to 
their construction materials and techniques. Therefore, 
as the rebuilt rooms are built of contemporary 
materials, the thermal properties of the building 
envelope were determined by the materials of the 
external walls, floor, roof, and thickness. The 
calculated U-values showed that the building envelope 
of the original rooms of Dana hotel resisted heat 
transfer better than the rebuilt rooms, confirming the 
results of the previous studies. However, along with the 
materials, the building design also influences the 
resulting indoor conditions, including the opening sizes 
and orientation (Fernandes et al., 2015). Therefore, 
monitoring the internal thermal conditions was 
conducted to show the total impact of the building 
design.  

The results showed that the rebuilt rooms provided 
stable indoor temperatures, although they do not 
provide the same thermal mass due to the effect of 
opening sizes and orientation. This highlighted that 
although the new construction materials provide higher 
U-values and less thermal resistance, the rebuilt rooms 
provided lower temperatures with a lower diurnal 
swing in summer, contradicting previous studies. 
Overall, the analysis from the monitoring conducted 
showed different behaviour between the original and 

rebuilt part of Dana hotel in summer, while similar 
behaviour was noticed in winter (Table 6). It 
highlighted that the indoor temperatures were higher in 
the original rooms, showing more variations in 
summer. Furthermore, both the original and rebuilt 
rooms provided thermal comfort in summer, with the 
rebuilt rooms offering slightly better comfort. This 
research could be expanded by conducting thermal 
simulation to advance the heat transfer analysis, 
showing the efficiency of the building’s envelope and 
its components in resisting heat transfer. Moreover, 
discussing the comfort responses and adaptive 
behaviour of occupants through a post-occupancy 
evaluation survey would help identify challenges and 
suggest potential solutions to the original and rebuilt 
buildings.   
 
CONFLICT OF INTEREST 
 
The authors declare no conflict of interest. 
 
FUNDING 
 
No funding was received for this project. 
 
REFERENCES 
 
Al Haija, A. A. (2011). Jordan: Tourism and conflict 

with local communities. Habitat 
International, 35(1): 93-100. 

Alzoubi, H. H., & Almalkawi, A. T. (2019). A 
comparative study for the traditional and modern 
houses in terms of thermal comfort and energy 
consumption in Umm Qais city, Jordan. Journal of 
Ecological Engineering, 20(5): 14-22. 

Bodach, S., Lang, W., & Hamhaber, J. (2014). Climate 
responsive building design strategies of vernacular 
architecture in Nepal. Energy and Buildings, 81: 
227-242. 

Fernandes, J., Mateus, R., Bragança, L. and Correia da 
Silva, J.J., 2015. Portuguese vernacular 
architecture: the contribution of vernacular 
materials and design approaches for sustainable 
construction. Architectural Science Review, 58(4): 
324-336. 

Meier, I. A., Roaf, S. C., Gileard, I., Runsheng, T., 
Stavi, I., & Mackenzie-Bennett, J. (2004). The 
vernacular and the Environment towards a 
comprehensive Research methodology. In Proc. 
21st Int. Conf. on PLEA (Vol. 2, pp. 719-724). 



A Comparison Study between the Thermal Performance of the Original and Rebuilt Vernacular Buildings of 
Dana Village in Jordan   

90  

Nicol, F., Humphreys, M., & Roaf, S. (2012). Adaptive 
thermal comfort: principles and practice. 
Routledge. 

Philokyprou, M., Michael, A., & Thravalou, S. (2013). 
Assessment of the bioclimatic elements of 
vernacular architecture. The historic centre of 
Nicosia, Cyprus. In Conference Proceedings, Le 
Vie dei Mercanti XI Forum Internazionale di Studi, 
Aversa, Capri (pp. 13-15).  

Philokyprou, M., Michael, A., Malaktou, E., & Savv-

ides, A. (2017). Environmentally responsive design   
In   Eastern   Mediterranean.  The  case  of 
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mountainous regions of Cyprus. Building and 
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Weber, W. and Yannas, S. eds., 2013. Lessons from 
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https://en.climate-data.org/asia/jordan/dana/dana-
459275/#temperature-graph. Retrieved 
June,21,2020. 

 


	روان اللوزي*، نيكولاس كاريديس، ماريالينا نيكولوبولو
	1. INTRODUCTION
	2. DANA HOTEL
	3. METHODOLOGY
	4. RESULTS
	4.1. Thermal Environment
	4.1.1.  Air temperatures in the original rooms
	4.1.2.  Air temperatures in the rebuilt rooms
	4.1.3. Comparison between temperatures in the original and rebuilt rooms
	4.2. Thermal Comfort
	4.2.1. Thermal comfort in the original rooms
	4.2.2.  Thermal comfort in the rebuilt rooms
	4.2.3. Comparison between thermal comfort at the original and rebuilt rooms

	5. DISCUSSION AND CONCLUSION
	CONFLICT OF INTEREST
	FUNDING
	No funding was received for this project.

	REFERENCES