J. Build. Mater. Struct. (2017) 4: 50-57 Original Article  
DOI : 10.34118/jbms.v4i2.31  

 

ISSN  2353-0057, EISSN : 2600-6936 

The effect of building materials choice on the thermal comfort in the 
self-produced individual housing in Biskra. 

Latreche S*, Sriti L  

     Department of Architecture , University of Biskra, BP 145 RP, 07000 Biskra, Algeria  
* Corresponding Author: sihem.latreche21@gmail.com 

 

Abstract. The building envelope is the first barrier to protect against external climatic 
variations. Generally, it consists of two types of walls: opaque walls (walls and roof) and 
transparent walls (Windows). The design characteristics of the enclosure strongly affect the 
occupants' thermal comfort, as well as the building energy consumption. The constructive 
choices relating to structural elements, in particular, walls, roofing and openings are 
generally considered in the thermal exchanges between the building and its environment. In 
the present study, which is based on experimental analysis in the self-generated residential 
sector in Biskra (Algeria), where a warm and arid climate predominates, we aim to evaluate 
the thermal impact of certain architectural and constructive parameters that are specific to 
residential habitat self-produced in Biskra.  This paper summarizes the main results 
obtained from an in situ measurement campaign that evaluated the essential parameters of 
thermal comfort such as ambient and surface temperature, air velocity, and humidity. These 
parameters were used as indicators to measure the impact of the envelope material 
characteristics on its climatic adaptability. This paper also presents some recommendations 
for optimizing the choice of building materials specific to the self-produced residential in 
order to improve its thermal performance while preserving the essentials of its specificities. 

Key words: Construction materials, thermal comfort, Individual housing self-produced, hot and arid 
climate, Biskra.

1. Introduction 

In Algeria, there are several reasons for the evolution of the constructive system in the 
individual housing, in particular the appearance of new materials and construction techniques 
as well as new modes of architectural design. Unfortunately, this revolution in architectural 
practice has ignored the specificities of the climate context, which has led to a rupture between 
the framework and its environment and an abusive and irrational exploitation of the resources 
Energy. Thus, electricity consumption in the residential sector in Algeria represents 28% of the 
total consumption of electricity (APRUE, 2015). This consumption is essentially, intended to 
cover the needs of artificial lighting, heating and air conditioning (Figure. 1); it is experiencing a 
growing trend in particular for the residential sector (Figure.2). 

  

Fig. 1. Distribution of energy consumption by sector in 
Algeria (Source: APRUE, 2015). 

Fig. 2. Evolution of energy consumption by sector in tep 
(Source: APRUE, 2015). 

mailto:sihem.latreche21@gmail.com


 Latreche and Sriti., J. Build. Mater. Struct. (2017) 4: 50-57 51 

 

 

The city of Biskra, which is characterized by a hot and arid climate, illustrates the magnitude of 
this phenomenon. Since a few decades, the built frame produced in this city has no relation with 
the climatic conditions, which drives the inhabitants to turn to the mechanical means to ensure a 
certain level of comfort whose cost is each year more High. In addition, it is to reduce this energy 
consumption and ensure optimum climatic comfort that must be taken on architectural design.   

As such, the design characteristics of the envelope strongly affect the thermal comfort of the 
occupants, as well as the energy consumption in the building. The climate and energy 
performance of the envelope depends on the constructive choices relating to the structural 
elements, in particular the walls, the roof and the openings generally considered as determining 
factors in trade between the building and its environment. 

The objective of this study is to evaluate the thermal impact of the structural and constructive 
elements of the envelope as they are used in the residential housing produced in Biskra. The 
ultimate goal of our research is to improve the thermal performance of the architectural 
envelope of this type of habitat and thus reduce energy consumption through passive solutions. 

2. The climatic characteristics of the wilaya of BISKRA 

The city of Biskra is located in the South-east of Algeria at a latitude of 34.80 ° North and 
longitude of 5.73 ° East (Figure. 3). Biskra belongs to a region classified arid, where a hot and dry 
climate with cold winters and hot summers predominates. The maximum temperature reaches 
42C° during the month of July and the minimum temperature decreases to 7 C° in winter during 
the month of January. The average annual temperature is 21.7 C°, while the average annual 
humidity is 46%. Very low precipitation is recorded with a maximum of 20 mm/year, and an 
annual average of about 8.8mm/year. The directions of prevailing wind is North-west in winter, 
South-east in summer at a speed from 6 to 10 m/s (Figure.4). 

 

  

 

Fig 3: Situation of the Wilaya of Biskra (Source: google earth) 

 

 

 

 



52 Latreche and Sriti., J. Build. Mater. Struct. (2017) 4: 50-57  

 

 

  

  

Fig 4: Climatic data of the city of Biskra (Source: Weather station data Biskra, 2000-2009) 

According to Givoni (1978), to assure the hygrothermal comfort under a dry hot climate, the 
buildings must be adapted to the summer conditions and it assuming that a building where the 
comfort is assured in summer will satisfy the winter requirements. In this study, it will be 
limited to the presentation of the results obtained during the summer period. 

3. The building envelope and thermal comfort 

From ancient times up to the present day, the man did not stop improving his housing 
environment to assure a protection always more effective against weather conditions and 
aggressive factors of the external environment. However, thermal comfort in a building depends 
mainly on the thermal behaviour of its envelope (Fig. 5) More precisely are the building 
materials and the architectural and constructive characteristics of the structural elements (wall 
thickness, compositions, layout ... etc.), which determine the climatic adaptability of a 
construction.  

The outside envelope of the building is its first barrier of protection; it consists of two types of 
walls: opaque walls (walls and roof) and transparent walls (Windows). The roof is responsible 
for 70.62% of the gains received while 27.11% of the thermal gains are transmitted by the four 
facades, and 2.27% by the windows (Necib, 2016). A judicious treatment of the walls of the 
envelope according to the warm and arid climatic conditions (choice of construction materials 
with high thermal inertia for walls and roofing, reduction of the dimensions of windows, solar 
protections ... etc.) allows to guarantee an optimal comfort inside the building, even if the outside 
conditions are unfavorable (Izard, 1979). 

 



 Latreche and Sriti., J. Build. Mater. Struct. (2017) 4: 50-57 53 

 

 

 

Fig. 5: The outside envelope undergoes numerous aggressions of the local climate and the environment 

(source: Hauglustaine, 2006) 

4. Experimental study 

Our analytical work based on a survey in situ intended for the study of the structural and 
constructive parameters of the envelope influence on the thermal comfort. This one is measured 
from the ambient and surface temperature, the air speed, and the relative humidity. The 
measuring instrument TESTO was used to raise the variations of the previous three 
hygrothermal parameters while the surface temperature was measured with an infrared 
thermometer (figure. 6). The measures were made inside, outside of the room, and in various 
points, in particular the roof and the wall of facade (Figure.7). 

To select houses to be studied, it was necessary to perform a typo-morphological analysis. An 
important corpus of contemporary individual self-produced in Biskra was assembled. The 
houses were distributed in different planned subdivisions of the city and their choice was made 
according to the characteristics of the most recurring envelope (orientation, building materials, 
ratio of openings, number of levels ... etc.). In total, 15 variants of rooms were studied. 

The analysis of the climatic data of Biskra allowed us to determine the period of overheating, 
which is approximately one week from the end of July to the beginning of August. The recording 
of the measurements took place at two times of the day from 14 pm to 16 pm in the afternoon 
and from 9 am to 11 am in the morning.  

  

Fig. 6 : Measuring instrument TESTO and 
infrared thermometer 

Fig. 7: Position of measurement points in the room  



54 Latreche and Sriti., J. Build. Mater. Struct. (2017) 4: 50-57  

 

 

In order to study the impact of the building materials used at the envelope level, several cases 
have been chosen. The sample includes 15 variants that illustrate the different constructive 
systems of exterior walls used in the Biskra (Table 1). In addition to the walls, two other 
parameters have been taken into account: the orientation and position of the room in the house 
is in the ground floor (unexposed roof, floor), or on the upper level (exposed roof, terrace).  

 
Table 1:  Distribution of the 15 variants of the studied pieces  

Distributions of the 15 variants of parts studied according to the construction material 

Walls in hollow 

perpend ( 2 

variants) 

Walls in full 

perpend ( 1 

variant) 

Walls simple brick-

built of 15cm (4 

variants in the 

floor) 

Walls brick-built double 

of 15cm X2 (2var. RDC, 

3var. R+1) 

Walls brick with blade 

of air (1var double. 

RDC, 2var. R+1) 

     

To illustrate the obtained results at the end of the campaign of measure, it was chosen to present 
some examples showing the parameters of thermal comfort (temperature, relative humidity, air 
velocity) measured in parts that differ according to Three parameters: the physical and 
constructive characteristics of the walls, the orientation and the type of roofing (floor or terrace) 
(Table 2). 

 
Table 2: Examples of results of the measures made in situ in rooms using various building materials for walls;  
 

 

Wall in hollow brick 

(17cm), located on 

the floor, orientation 

South 

  
 

Ambient temperature C ° 

 
Morning Afternoon 

Max Min Moy Max Min Moy 

Temp inside  35.2  34.6  34.8 39 36.8 38 

Temp outside 39.1 33.1 37.8 44 40 41.5 

Thermal gap 4 1.5 3  5 3.2 3.5 

Surface temperature C ° 

Temp surf insi wall 36.4  / 36.4 38.5  / 37.6 

Temp surf outs wall 40.6  / 40.1  46.9  / 45.6 

Thermal gap 4.2 / 3.7 8.4 / 8 

Temp surf insi roof 36.8 / 36.6 37.5  / 37.5 

Temp surf outs wall 42.6  / 42  41.6  / 41.2 

Thermal gap 5.8 / 5.4 4.1 / 3.7 

Relative Humidity % 

Humidity indoor 26.4 24.8 25.6 26.3 22.5 24.2 

Humidity outside 20.3 19.7 20 14 13 13.3 

 

Walls brick with 

blade of air  33cm  

located on the floor,  

orientation west  

 
 

Ambient temperature C ° 

 
Morning Afternoon 

Max Min Moy Max Min Moy 

Temp inside 41.3 33.3 32.5 36.6 34 36.3  

Temp outside 37.3 37.2 37 42.3 41 41.8 

       Thermal gap 4 3.9 4.5 5.7 5 5.5 

Surface temperature C ° 

Temp surf insi wall 37.7  / 37.6 38.5  / 38.1 

Temp surf outs wall 41.6  / 41.4 49  / 48.4 

Thermal gap 4 / 3.8 10.5 / 10.3 

Temp surf insi roof 38.4 / 38.1 39.6 / 39.3 

Temp surf outs wall 34.4  / 34.4 46.8  / 46.4 

Thermal gap 4 / 3.7 7.2 / 7.1 

Relative Humidity % 

Humidity indoor 25.9 24.7 25.4 20.6 20 20.3 

Humidity outside 21.8 20.6 21.2 13.9 13 13.3 



 Latreche and Sriti., J. Build. Mater. Struct. (2017) 4: 50-57 55 

 

 

Air speed m / s 

Air Speed inside   0,3  0 0,1  0,3   0 0,1  

Air Speed outside  1,3  0,3 0.6   1,9  0,5  1.2 
 

 

Air speed m / s 

Air Speed inside  0.5 0 0.2 0.3 0 0.1 

Air Speed outside  1 0.3 0.5 1.9 0.5 1.2 

 
 

Wall in hollow brick 

15+15 (32 cm), 

located on the floor, 

orientation North-

west 

 

 

 

Ambient temperature C ° 

 
Morning Afternoon 

Max Min Moy Max Min Moy 

Temp inside  35,3  35,3 35,3   38  37,6  37,8 

Temp outside  39,6  38 39,2   42,8 34,3  42,6  

Thermal gap 4.3 2.7 4 4.8 3.3 4.8 

Surface temperature C ° 

Temp surf insi wall 35  /  34.1 38,5   /  38 

Temp surf outs wall  38.3  / 36.5   45,5  /  44,7 

Thermal gap 3.3 / 2.4 7 / 6.7 

Temp surf insi roof 38,4 / 38,4 38,8  /  38,7 

Temp surf outs wall 35,8 / 34,7  47,5 / 47,1  

Thermal gap 2.6 / 3.7 8.7 / 8.4 

Relative Humidity % 

Humidity indoor 30,7  26,7 29  26,7  20  21,8  

Humidity outside  23,2  20,4 21,6  15,4  14,8   15,5 

Air speed m / s 

Air Speed inside    0,3 0  0,1 0,3   0  0 

Air Speed outside  1,9 0,3  0,7   0,5    0,3 
 

 

 

Walls in full 

perpend (20cm) 

located on the 

ground floor , 

orientation west 

 

 

Ambient temperature C °° 

 
Morning Afternoon 

Max Min Moy Max Min Moy 

Temp inside 37,4 37 37,1 40,3 40,1 40,2 

Temp outside 40 39 39,7 41.5 40,8 41 

       Thermal gap 2.6 2 2.6 1.2 0.7 0.8 

Surface temperature C ° 

Temp surf insi wall 36,4   /  37,1 42,1 / 41,7 

Temp surf outs wall  41,2  / 41  45,4 / 45 

Thermal gap 4.8 / 3.9 3.3 / 3.3 

Temp surf insi roof 37,1   /  37 44,7 / 44,3 

Temp surf outs wall  39,2  / 38,6  50,6 / 49 

Thermal gap 2.1 / 1.6 5.9 / 4.7 

Relative Humidity % 

Humidity indoor 31,1  24,2  26,1 21,4 19 19,6 

Humidity outside  21,8  21,6  21,7 19,4 17,5 18,2 

Air speed m / s 

Air Speed inside       0 0  0  0 0 0 

Air Speed outside  1,4  0,4  0,8  0,5 0 0,3 

 

Walls in hollow 

perpend  (22cm) 

located on the ground 

floor south-west 

orientation 
               

Ambient temperature C ° 

 

Morning Afternoon 

Max Min Moy Max Min Moy 

Temp inside 32,2 32 32,1 37,7 34,7 36,5 

Temp outside 34,8 34 34.3 41,1 38,4 37.5 

       Thermal gap 2.6 2 2.2 3.4 0.5 1 

Surface temperature C ° 

Temp surf insi wall 31,5 / 31,2 37,2 / 36.9 

Temp surf outs wall 35,8 / 35,4 45,7 / 45 

Thermal gap 4.3 / 4.2 8.5 / 8.1 

Relative Humidity % 

Humidity indoor 39,4 34,8 35,6 32,1 26,2 29,4 

Humidity outside 32,8 31,3 31,8 21,5 17,9 20 

Air speed m / s 

Air Speed inside  0.5 0 0,1 0,6 0,0 0,1 

Air Speed outside  2.1 0.3 1 2,6 0,3 1 



56 Latreche and Sriti., J. Build. Mater. Struct. (2017) 4: 50-57  

 

 

5. Interpretation of the results 

5.1 Air temperature 

According to Bennadji (1999), the subtraction of the external average temperatures from those 
of the interior of the room allows to appreciate the temperature difference between the inside 
and the outside. In table 2, it is noted that there is a difference of 0.5 C ° to 2 C ° between these 
two temperatures in a house built in single wall (single partition). The maximum value of 
ambient temperature is recorded in houses built in hollow and full block; for these cases, the 
indoor temperature is in the order of 32 ° to 38 ° at the time when the outside temperature 
reaches the 40 °. This constructive choice is visibly inadequate for the warm and arid climate. 
For the rooms built on the floor the situation of discomfort is at its extreme, for example for a 
piece built in single 15 cm brick wall, the average temperature difference is in the order of 3 C ° 
to 3.5 C °. 

On the other hand, in the houses built in double partition, the temperature difference is more 
appreciable. As an example, for double brick walls of 15 cm, it is between 4 C ° to 4.5 C ° (the 
internal temperature reaches 23.5 C °, outside it is 26.5 C °). In the case of double walled walls 
with a blade of air, the thermal gap between the inside and outside is optimal in the order of 5 C 
to 5.5 C °. 

In conclusion, it appears that the highest indoor temperatures are recorded in simple walled 
rooms with low thermal resistance materials such as hollow and full block. On the other hand, 
the walls in double walls give more interesting results from the point of view of thermal comfort 
in the summer period. Note that the ambient temperatures measured are also dependent on 
other factors such as orientation and external climatic fluctuations. 
 

5.2. The relative humidity and the air speed 

When reading the results of the measurements, we can be said that the external relative 
humidity is low compared to the internal humidity, on the outside it usually varies between 15% 
and 19% and inside it is between 22% and 31%. These results can be explained by human 
metabolism vapor and domestic activities and also the lack of aeration in the house. 

According to Liebard (2005), the air velocity that does not exceed 0.2 m/s in the habitat has an 
influence on convective heat exchanges. However, with respect to the parts tested, the air 
velocity was very low not exceeding 0.1 m/s due to the lack of transverse ventilation. 
 

5.3. The values of the surface temperature 

According to Szokolay (2004), the temperature of the external surface has great effects on the 
internal thermal conditions; moreover, it varies with the clarity of the color and the velocity of 
the air in contact with the surface. Based on the results obtained, it appears that the 
temperatures of the internal surfaces are higher than the ambient temperature when the walls 
are exposed to solar radiation. Thus, the higher the external surface temperature increases due 
to the lack of shading and the lack of solar protections at the level of openings, the higher the 
ambient temperature rises in proportion to the external surface temperature. The temperature 
of the air and the surface temperature are therefore linked both by the amount of the incident 
solar radiation and also by the thermo-physical properties of the building materials, which 
retard the transfer of the heat inside. 
 
 
 
 
 
 



 Latreche and Sriti., J. Build. Mater. Struct. (2017) 4: 50-57 57 

 

 

6. Conclusions 

Through an experimental in situ study of a single-detached houses corpus in Biskra, the 
influence of the structural and constructive choices of the architectural envelope on the inner 
thermal comfort was examined. This experiment has shown that a judicious choice of materials 
can positively influence the inner thermal comfort, especially thanks to the thermo-physical 
properties of the materials that allow regulating heat exchanges between the building and its 
environment. The double-walled walls offer some advantages from the point of view of thermal 
comfort during the summer period. Moreover, the thermal operation of the enclosure can be 
optimized thanks to the integration of the solar protections according to the orientation of the 
façade. 

7. References 

APRUE, (2015). Final energy consumption of Algeria, key figure-year 2015; Ministry of Energy and Mines. 

Bennadji, A. (1999). Climatic or cultural Adaptation in arid zones: case of the Algerian South-East. PhD 
thesis. Université d'Aix-Marseille1-Université de Provence. 

Hauglustaine J.-M. (2006). The Global Conception of the envelope and the energy, a practical Guide for 
architects; Ministry of the Walloon Region; February 2006. 

Givoni, B. (1978). Man architecture and climate. Editions Le Moniteur, Paris, France, 460 p. 

Izard, J. L. (1979). Archi Bio; Editions parentheses; Roquevaire, 1979. 

Liebard, A. (2005). Treatise on Bioclimatic Architecture and urbanism: design, build and develop with 
sustainable development. Editions Le Moniteur, Paris, France, 2005. 

Necib, H (2016). Improved thermal insulation of habitats in warm and arid regions. Third International 
Conference on Energy, materials, Applied Energetic And Pollution. ICEMAEP 2016; Constantine, 
Algeria 

Szokolay, V. (2004). Introduction to architectural science, the basis of sustainable design. Architectural 
Press Edition, edition An imprint of Elsevier Science, 348p.