58

The Effect of the U Value in the Energy Performance of Residential 
Buildings in Greece

Dimitrios Bikas, Panagiotis Chastas*

Aristotle University of Thessaloniki, Dept. of  Civil Engineering, Laboratory of Building Construction and Building 
Physics, 54124 Thessaloniki, Greece.

*Corresponding author: pchastas@civil.auth.gr

  http://dx.doi.org/10.5755/j01.sace.6.1.5950

According to the European 2012/31/EE Directive all new buildings until 31/12/2020 and all new buildings occupied 
by public authorities until 31/12/2018 should be buildings with nearly zero energy consumption. Many countries of the 
European Union have established legislation with provisions for the energy performance of the buildings with a further 
goal to reach the nearly zero energy consumption building. In Greece there is a presence of this attempt from the year 2010 
with the Regulation of the Energy Performance in Buildings (ΚΕΝΑΚ, 2010). This was a first attempt for upgrading the 
energy performance and for establishing the energy inspection of buildings and the relative provisions. In order to achieve 
the goal and fulfill the requirements of the European legislation a further attempt should be focused in interventions such 
as lower U value limits in the opaque building elements of the building envelope and windows, in upgrading the energy 
efficiency of HVAC systems and even the use of renewable sources to cover a percentage of the energy requirements of 
the buildings. This study aims to evaluate the effect of the reduction of the U value of the opaque building elements in the 
energy requirements and consumption in residential buildings in Greece, according the climatic zone that is located, as a 
step closer to the nearly zero energy consumption building.

Keywords: nearly zero energy building, residential buildings, energy consumption, U value, opaque building elements. 

DARNIOJI ARCHITEKTŪRA IR STATYBA
2014. No. 1(6) 

JOURNAL OF SUSTAINABLE ARCHITECTURE AND CIVIL ENGINEERING
ISSN 2029–9990

1. Introduction

Greece is one of the one of the 27 state members of the 
European Union that has established commitments towards 
the nearly zero energy building, such as penalties for energy 
performance requirement non-compliance and incentives 
for nearly zero energy buildings and for rent of energy 
efficient buildings (Ó Broin, Mata, Göransson, & Johnsson, 
2013).  This is presented by the Greek Regulation of Energy 
Performance of Buildings (KENAK) which with the laws 
3851/2010 and 3889/2010 regulates the basic principles of 
operation and management of energy performance and the 
basic legislation for Renewable energy. 

The Regulation of Energy Performance of Buildings 
aims to improve the energy efficiency of new buildings in 
Greece and of the building stock that is consisted of buildings 
which have incomplete or inadequate thermal protection. Its 
goal is to reduce the consumption of conventional energy 
for heating, cooling, air conditioning, lighting and hot water 
while ensuring the comfort of the interior of buildings. This 
is achieved with energy efficient design of the building 
envelope, use of energy efficient building materials and 
electrical/mechanical equipment, renewable energy sources 
and CHP systems (ΤΟΤΕΕ20701−1, 2010). 

With all these efforts for energy upgrading of 
buildings in line with the Greek legislation in 2013 by Law 
4122/2013 the European 2012/31/EE Directive. Its aim is to 
review periodically the provisions on energy performance 
of buildings aiming all new buildings until 31/12/2020 
and all new buildings occupied by public authorities 
until 31/12/2018 to be buildings with nearly zero energy 
consumption. In order to achieve the demanding minimum 
requirements of the energy performance in buildings, 
interventions are proposed in the international literature for 
the energy upgrading of the opaque surface of the building 
envelope with new lower requirements of the U value and 
higher thickness of the insulating material or improved 
window glazing forms (Thalfeldta, Pikas, Kurnitski, & Voll, 
2013). Also another approach is the upgrading of the HVAC 
systems of the building in order to reduce the annual energy 
consumption with improvements of the efficiency ratio 
and the automation of the systems. Furthermore the use of 
renewable sources of energy, such as photovoltaic systems, 
micro-wind turbines etc. is considered in order to cover 
a percentage of the energy requirements of the building 
(Desideri  et al., 2013).



59

This study aims to evaluate the attempts of the energy 
upgrading of the opaque surface of the building envelope 
in residential buildings in Greece. Furthermore is to 
quantify the effect of the reduction of the U value of the 
opaque building elements to the annual primary energy 
consumption by end use and the annual requirements for 
heating and cooling depending of the climatic zone that is 
located.

2. Methods

2.1. The effect of the U value in the consumption of energy
In this analysis was examined the effect of the 

reduction of the U value in the energy performance of 
residential buildings and specifically in the annual primary 
energy consumption  by end use and the annual energy 
requirements for heating and cooling.

The typical construction that was examined is provided 
for tests by ISO 13790/2008 (table 1) and takes no account 
of thermal bridges. 

Table 1. Dimensions of construction (ISO13790, 2008)

Building element Area (m2)
West wall 10.08

Window glazing 7.00
North wall 15.40
South wall 15.40
East wall 10.08

Floor 19.80
Roof-ceiling 19.80

The effect of the U value was examined for the opaque 
building elements that compose the building envelope of 
residential buildings in Greece (table 2).

Table 2. Maximum value of thermal transmittance (W/m2.K) per 
climatic zone in Greece according to the Regulation of Energy 
Performance in Buildings

Building 
elements

Climatic 
zone Α

Climatic 
zone Β

Climatic 
zone Γ

Climatic 
zone Δ

External flat or 
inclined roof

0.50 0.45 0.40 0.35

External 
vertical building 

elements 
0.60 0.50 0.45 0.40

Windows and 
doors

3.20 3.00 2.80 2.60

Flooring over 
pilotis

0.50 0.45 0.40 0.35

To calculate the contribution of the reduction of U 
value in the consumption of energy the maximum U value  
(table 2), depending on the climatic zone, of all building 
elements is imported. Then the U value of the examined 
element is changing with a descending step 0.05 W/m2.K while 
all the other building elements keep their original maximum U 
value. The procedure is carried out for all the opaque building 
elements and for the four climatic zones that Greece is divided 
according to the climatic conditions of each region.

2.2. Climatic zones of Greece according to the Regulation of 
Energy Performance in Buildings

According to KENAK Greece is divided into four 
climatic zones depending on the heating degree days of 
each region. The schematic depiction (Fig. 1) defines the 
regions located in the four climatic zones, from the warmer 
(climatic zone A) to the coldest (climatic zone Δ).  In each 
region of a climatic zone that is located in an altitude over 
500 meter, is considered to be in the next colder climatic 
zone than the one they are originally located. All regions 
located in climatic zone Δ regardless of altitude are included 
in this zone (ΤΟΤΕΕ20701−3, 2010).

Fig. 1. Climatic zones of Greece (ΤΟΤΕΕ20701−3, 2010)

2.3. Software TEE KENAK 
The software that was used for this analysis is TEE 

KENAK. This software is used to process the Energy 
Inspection of buildings and to issue the energy performance 
certificate. Also is used for calculations and the classification 
that is required for the study of Energy Efficiency in 
buildings, boilers and heating and air conditioning systems. 
It was developed by the Group of Energy Conservation, 
the Institute for Environmental Research and Sustainable 
Development and the National Observatory of Athens in the 
framework of the cooperation program with the Technical 
Chamber of Greece (TEE). It was created in accordance 
with European and national standards, the Greek Regulation 
of Energy Performance of Buildings and the associated 
Technical Instructions of the Technical Chamber of Greece 
(TOTEE). 

The core of the calculations of the software is based on 
the pre-existing software EPA-NR (version 1.7.6.19), which 
was developed under the European Programme Intelligent 
Energy of Europe, 17th GD EU (EIE/04/125/S07.38651), 
and has been suitably modified to be consistent with the 
national requirements in Greece, as provided in Regulation 
of Energy Performance in Buildings and related Technical 
Instructions of the Technical Chamber of Greece. The 
software uses the monthly method for the calculation of 
the energy requirements and consumption for heating and 
cooling as it is defined by ISO 13790/2008. This method 
includes the calculation of the heat transfer by transmission 



60

and ventilation, the calculation of the annual energy 
requirements and energy consumption for heating and 
cooling and the solar and internal heat gains (ISO13790, 
2008).

For the completeness of this analysis it was considered 
a theoretical heating system with an oil boiler with an 
efficiency ratio 0.935, a distribution network of hot water 
for the transmittance of the heat with an efficiency ratio 
0.95, terminal units (radiators) with an efficiency ratio 
0.93 and supporting units with power 0.1 W/m2. For the air 
conditioning system was considered a theoretical cooling 
system with air-cooled heat pumps with an EER 3.0 and an 
average monthly coverage of the required cooling energy 
0.5, a distribution network with an efficiency ratio 1.0, 
terminal units with efficiency ratio 0.93 and supporting 
units with power 0.0 W/m2 (ΤΟΤΕΕ20701−1, 2010).

3. Results

3.1. Vertical building elements of the opaque surface of the 
building envelope

The reduction of the U value (Fig. 2) in climatic zone 
A by 0.01 W/m2.K leads to a reduction in the annual energy 
requirements for heating 0.518 kWh/m2 and in climatic zone 
B 0.562 kWh/m2. The same change of the U value leads to 
a reduction of 1.032 kWh/m2 in zone Γ and 1.364 kWh/m2 
in zone Δ (table 3). 

Fig. 2. Reduction of annual energy requirements for heating for 
the change of U value of the vertical building elements for the four 
climatic zones

Fig. 3. Reduction of annual energy requirements for cooling for 
the change of U value of the vertical building elements for the four 
climatic zones

Fig. 4. Reduction of annual primary energy consumption by end 
use for the change of U value of the vertical building elements for 
the four climatic zones

The annual energy requirements for cooling appear 
to have small changes in all four climatic zones between 
the original and the final U value (Fig. 3). A decrease  
0.075 kWh/m2 is observed in climatic zone A and a decrease 
0.073 kWh/m2 in climatic zone B. An increase 0.011 kWh/m2 
is observed in climatic zone Γ and 0.057 kWh/m2 in climatic 
zone Δ for the reduction of the U value by 0.01 W/m2.K 
(table 3). 

The reduction of the U value in climatic zone A  
(Fig. 4) by 0.01 W/m2.K leads to a reduction in the annual 
primary energy consumption by end use 0.733 kWh/m2 and 
in climatic zone B 0.793 kWh/m2. In climatic zones Γ and 
Δ the same change of the U value leads to a reduction of  
1.331 kWh/m2 in zone Γ and 1.725 kWh/m2 in zone Δ (table 3).

Table 3. Effect of the reduction of the U value by 0.01 W/m2.K to 
the annual energy requirements for heating and cooling and the 
annual primary energy consumption by end use 

Vertical building 
elements

Reduction of U value 0.01 W/m2.K

Climatic 
zone A

Climatic 
zone B

Climatic 
zone Γ

Climatic 
zone Δ

Annual 
primary energy 
consumption by 

end use (kWh/m2)

-0.733 -0.793 -1.331 -1.725

Annual energy 
requirements for 

heating (kWh/m2)
-0.518 -0.562 -1.032 -1.364

Annual energy 
requirements for 

cooling (kWh/m2)
-0.075 -0.073 +0.011 +0.057

Evaluation
As it is observed (Fig. 5) the reduction of the energy 

requirements for heating follows about the same change 
as the effect of the reduction of the U value between the 
four climatic zones and for a point of reference the values 
of climatic zone A. From the transaction from climatic 
zone A to B the changes in these parameters are minor 
with a percentage 6.6–8.5 %. From climatic zone A to Γ a 
difference is observed of 99.4–105.6 % and from climatic 
zone A to Δ 163.4–173.2 %.



61

Fig. 5. The reduction of the U value and of the annual energy 
requirements for heating between the four climatic zones

Between the reduction in the primary energy 
consumption by end use and the effect of the U value a 
significant difference is observed in the percentage change 
(Fig. 6). The percentage change of the effect of the reduction 
of the U value from climatic zone A to Β is 8.2 %, from 
zone A to Γ 81.7 % and from zone A to Δ 135.5. The average 
percentage change in the reduction of the primary energy 
consumption by end use from climatic zone A to B is 2.9 %, 
from zone A to Γ is 56.5 % and from zone Γ to Δ is 85.8 %. 
This can be explained by the influence of a number of other 
parameters to the final calculation of the primary energy by 
end use such as the technical parameters of the heating and 
cooling system (efficiency ratio, EER, automation of HVAC 
systems etc.) and the indicators used for the calculation of 
the contribution of the form of energy source. 

Fig. 6. The reduction of the U value and of the annual primary 
energy consumption by end use between the four climatic zones

3.2. Building element flooring over pilotis
The reduction of the U value in climatic zone A  

(Fig. 7) by 0.01 W/m2.K leads to a reduction in the annual 
energy requirements for heating 0.227 kWh/m2 and in 
climatic zone B 0.246 kWh/m2. In climatic zones Γ and 
Δ the same change of the U value leads to a reduction of  
0.444 kWh/m2 in zone Γ and 0.574 kWh/m2 in zone Δ (table 4). 

In the annual energy requirements for cooling  
(Fig. 8) an increase 0.024 kWh/m2 is observed in climatic 
zone A, in climatic zone B 0.025 kWh/m2, in climatic zone 
Γ 0.045 kWh/m2 and in climatic zone Δ 0.058 kWh/m2 for a 
reduction of the U value by 0.01 W/m2.K (table 4).

Fig. 7. Reduction of annual energy requirements for heating for 
the change of U value of the building element flooring over pilotis 
for the four climatic zones

Fig. 8. Reduction of annual energy requirements for cooling for 
the change of U value of the building element flooring over pilotis 
for the four climatic zones

Fig. 9. Reduction of annual primary energy consumption by end 
use for the change of U value of the building element flooring over 
pilotis for the four climatic zones

The reduction of the U value in climatic zone A by 
0.01 W/m2×K leads to a reduction in the annual primary 
energy consumption by end use (Fig. 9) 0.293 kWh/m2 and 
in climatic zone B 0.320 kWh/m2. In climatic zones Γ and 
Δ the same change of the U value leads to a reduction of  
0.550 kWh/m2 in zone Γ and 0.706 kWh/m2 in zone Δ (table 4).



62

Table 4. Effect of the reduction of the U value by 0.01 W/m2.K to 
the annual energy requirements for heating and cooling and the 
annual primary energy consumption by end use 

Flooring over 
pilotis

Reduction of U value 0.01 W/m2.K
Climatic 
zone A

Climatic 
zone B

Climatic 
zone Γ

Climatic 
zone Δ

Annual 
primary energy 
consumption by 

end use (kWh/m2)

-0.293 -0.320 -0.550 -0.706

Annual energy 
requirements for 

heating (kWh/m2)
-0.227 -0.246 -0.444 -0.574

Annual energy 
requirements for 

cooling (kWh/m2)
+0.024 +0.025 +0.045 +0.058

Evaluation
As it is observed (Fig. 10) the reduction of the energy 

requirements for heating follows about the same change 
as the effect of the reduction of the U value between the 
four climatic zones and for a point of reference the values 
of climatic zone A. From the transaction from climatic 
zone A to B the changes in these parameters are minor 
with a percentage 0.0–8.2 %. From climatic zone A to Γ a 
difference is observed of 86.0–95.1 % and from climatic 
zone A to Δ 140.7–152.2 %.

Fig. 10. The reduction of the U value and of the annual energy 
requirements for heating between the four climatic zones

Fig. 11. Reduction of annual primary energy consumption for the 
change of U value of the vertical building elements for the four 
climatic zones

Between the reduction in the primary energy 
consumption by end use and the effect of the U value a 
significant difference is observed in the percentage change 
(Fig. 11). The percentage change to the effect of the 
reduction of the U value from climatic zone A to Β is 9.0 %, 
from zone A to Γ 87.5 % and from zone A to Δ 140.8 %. The 
average percentage change in the reduction of the primary 
energy consumption by end use from climatic zone A to B 
is 0.0 %, from zone A to Γ is 48.8 % and from zone Γ to Δ 
is 74.4 %. 

3.3. Building element roof 
The reduction of the U value (Fig. 12) in climatic zone 

A by 0.01 W/m2.K leads to a reduction in the annual energy 
requirements for heating 0.190 kWh/m2 and in climatic zone 
B 0.209 kWh/m2.In climatic zones Γ and Δ the same change 
of the U value leads to a reduction of 0.373 kWh/m2 in zone 
Γ and 0.510 kWh/m2 in zone Δ (table 5).

Fig. 12. The reduction of the U value and of the annual energy 
requirements for heating of the building element roof between the 
four climatic zones

In the annual energy requirements for cooling  
(Fig. 13) a decrease 0.094 kWh/m2 is observed in climatic 
zone A, in climatic zone B 0.082 kWh/m2, in climatic zone 
Γ 0.046 kWh/m2 and in climatic zone Δ 0.026 kWh/m2 for a 
reduction of the U value by 0.01 W/m2.K (table 5).

Fig. 13. Reduction of annual energy requirements for cooling for 
the change of U value of the building element roof for the four 
climatic zones

The reduction of the U value in climatic zone A by 
0.01 W/m2.K leads to a reduction in the annual primary 



63

energy consumption by end use (Fig. 14) 0.300 kWh/m2 
and in climatic zone B 0.323 kWh/m2. In climatic zones Γ 
and Δ the same change of the U value leads to a reduction 
of 0.508 kWh/m2 in zone Γ and 0.671 kWh/m2 in zone Δ 
(table 5).

Fig. 14. Reduction of annual primary energy consumption by end 
use for the change of U value of the building element roof for the 
four climatic zones

Table 5. Effect of the reduction of the U value by 0.01 W/m2.K to 
the annual energy requirements for heating and cooling and the 
annual primary energy consumption by end use 

Roof inclined 
or flat

Reduction of U value 0.01 W/m2.K
Climatic 
zone A

Climatic 
zone B

Climatic 
zone Γ

Climatic 
zone Δ

Annual 
primary energy 
consumption by 

end use (kWh/m2)

-0.300 -0.323 -0.508 -0.671

Annual energy 
requirements for 

heating (kWh/m2)
-0.190 -0.209 -0.373 -0.510

Annual energy 
requirements for 

cooling (kWh/m2)
-0.094 -0.082 -0.046 -0.026

Evaluation
Between the reduction in the energy requirements for 

heating and the effect of the U value (Fig. 15) a significant 
difference is observed in the percentage change. The 
percentage change to the effect of the reduction of the U 

Fig. 15. The reduction of the U value and of the annual energy 
requirements for heating between the four climatic zones

value from climatic zone A to Β is 9.8 %, from zone A to Γ 
96.2 % and from zone A to Δ 168.0 %. The average percentage 
change in the reduction of the energy requirements from 
climatic zone A to B is 0.0 %, from zone A to Γ is 84.9 % 
and from zone Γ to Δ is 137.9 %. 

Fig. 16. Reduction of annual primary energy consumption by end 
use for the change of U value of the building element roof for the 
four climatic zones

Between the reduction in the primary energy 
consumption by end use and the effect of the U value a 
significant difference is observed in the percentage change 
(Fig. 16). The percentage change to the effect of the 
reduction of the U value from climatic zone A to Β is 7.6 %, 
from zone A to Γ 69.2 % and from zone A to Δ 123.5 %. The 
average percentage change in the reduction of the primary 
energy consumption by end use from climatic zone A to B 
is 0.0 %, from zone A to Γ is 49.6 % and from zone Γ to Δ 
is 75.1 %. 

4. Discussion

In the typical construction that was examined in this 
study the reduction of the U value appears to have significant 
influence in all the opaque building elements. The greater 
reduction in the energy requirements and primary energy 
consumption by end use is observed in the vertical building 
elements in all four climatic zones. This could be explained 
from the fact that they cover a significant percentage of the 
area of the building envelope. This reduction in the other 
building elements is about 50 % of the reduction of the 
vertical building elements.

The reduction increases during the transaction from 
climatic zone A to climatic zone Δ. Between climatic zones A 
and B the change in the reduction of the energy requirements 
for heating for the descending step of the U value is about 
0.0–9.8 %. But in climatic zone Γ an increase 81.7–96.2 % 
and in climatic zone Δ 135.5–168.0 % is observed in all the 
opaque building elements of the building envelope. 

In the primary energy consumption by end use the 
vertical building elements appears to have twice the 
reduction of the other building elements in all climatic 
zones. This reduction increases from climatic zone A to B 
about 7.6–9.0 %, from B to Γ 69.2–87.5 % and from Γ to 
Δ 123.5–140.8 % in all the building elements. This lower 
effect of the U value in the primary energy by end use 
could be explained by the influence of a number of other 



64

parameters to the final calculation of the primary energy 
such as the technical parameters of the heating and cooling 
system (efficiency ratio, EER, automation of HVAC 
systems etc.) and the indicators used for the calculation of 
the contribution of the form of energy source. 

The effect of the U value in the change of energy 
requirements for cooling is about 90.0 % lower than the 
energy requirements for heating and the primary energy 
consumption by end use. An increase or a decrease is 
observed depending on the building element and the 
climatic zone. From climatic zone Γ to Δ an increase is 
mainly observed however its importance is minor due to 
the from the fact that is lower up to 90.0 % than the annual 
requirements for heating which overrides this difference 
and lead to a reduction of the annual primary energy 
consumption by end use. This increase could be explained 
from the fact that the reduction of the U value prevents outer 
temperatures, which are lower than climatic zones A and B, 
to be transferred in the internal of the building and reduce 
its temperature.

A reduction of the U value of 60 % from the maximum 
U value of all opaque building elements, in the typical 
construction of this study, leads to reduction 29.2 % in the 
annual primary energy consumption by end use in climatic 
zone A, in climatic zone B 27.9 %, in zone Γ 27.9 % and in 
climatic zone Δ 27.5 %.

5. Conclusions

The reduction of the U value of the opaque building 
elements of the building envelope is a first approach for 
the energy upgrading of buildings and a step closer to 
the buildings with nearly zero energy consumption. In 
all climatic zones the reduction of the U value leads to a 
significant reduction in the primary energy consumption by 
end use and in the energy requirements for heating. With 
the reduction of their U value a significant reduction to 
the energy requirements for heating is observed, with an 
increase from climatic zone Α to Δ between 137,9 % and 
173,2 %, depending on the building element. The same trend 
is observed in primary energy consumption by end use with 
an increase from climatic zone Α to Δ between 74,4 % and 
85,8 %. The reduction of the energy requirements for cooling 
seems to be minor in relation to the energy requirements 
for heating and the primary energy consumption. These 
reductions could lead up to 30 % lower energy consumption 
in residential buildings as a result of this study. However 
there is a distance from the final goal of the nearly zero 
energy building as the increase of the thickness of the 
insulating material should be considered in a cost optimal 
way. As a result other interventions and approaches could 
be considered, such as the effect of thermal transmittance 
of the windows of residential buildings in the energy 
consumption and the air tightness of the building. Windows 
with energy effective materials or increased number of 
window glazing could also be considered. Furthermore the 
upgrading of the efficiency of the HVAC systems and their 
automations would probably lead to a reduction of the energy 

consumption. Another approach that could be considered in 
this evaluation is the use of photovoltaic systems for the 
reduction of the energy consumption or other renewable 
energy sources and the use of solar panels for the reduction 
of the energy requirements for hot water.

On the way to meet the requirements of the nearly zero 
energy building only a combination of solutions, in a cost 
optimal way, would give the expected result.

Acknowledgment

This study was carried out for a diploma thesis in the 
MSc program “Environmental Protection and Sustainable 
Development” of the Department of Civil Engineering 
of Aristotle University of Thessaloniki. This paper was 
completed as a part of this MSc program and co-financed 
by the Act “Scholarships program SSF (State Scholarships 
Foundation/IKY) with an individualized assessment process 
of the academic year 2012-2013” from resources of the 
Operational Program “Education and Lifelong Learning”, 
of the European Social Fund (ESF) and the NSRF (2007-
2013).

References

Desideri U., Arcioni L., Leonardi D., Cesaretti L., Perugini P., 
Agabitini E.Evangelisti N., 2013. Design of a multipurpose 
“zero energy consumption” building according to European 
Directive 2010/31/EU: Architectural and technical plants 
solutions. Energy, Elsevier, Vol. 58, 157–167.

ISO13790, 2008. Energy performance of buildings - Calculation 
of energy use for space heating and cooling.

Ó Broin E., Mata É., Göransson A., Johnsson F., 2013. The effect of 
improved efficiency on energy savings in EU-27 buildings.   
Energy, Elsevier, Vol. 57, 134–148.

Thalfeldta M., Pikas E., Kurnitski J., Voll H., 2013. Facade 
design principles for nearly zero energy buildings in a cold 
climatic. Energy and Buildings, Elsevier, Vol. 67, 309–321.  
http://dx.doi.org/10.1016/j.enbuild.2013.08.027

ΚΕΝΑΚ, 2010. Αριθ. Δ6/Β/οικ. 5825. ΄Εγκριση Κανονισμού 
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της Ελληνικής Δημοκρατίας, 5333–5356, [Regulation of 
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παραμέτρων για τον υπολογισμό της ενεργειακής απόδοσης 
κτιρίων και την έκδοση του πιστοποιητικού ενεργειακής 
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Δημοκρατίας, Vol. 1387, 21435–21442. [Technical 
instructions of the Technical Chamber of Greece - Detailed 
national standards and parameters for calculating the energy 
performance of buildings and issuing energy performance 
certificate].

ΤΟΤΕΕ 20701−3, 2010. Κλιματικά δεδομένα ελληνικών περιοχών. 
Εφημερίς της Κυβερνήσεως της Ελληνικής Δημοκρατίας 
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Received 2013 12 16 
Accepted after revision 2014 02 08



65

Dimitrios BIKAS – Professor, Director Laboratory of Building Construction and Building Physics, Vice chairman of the 
Dept. of Civil Engineering. 
Main research area: Building construction, Building Physics, Energy efficiency of buildings, Sustainable building.
Address: Aristotle University of Thessaloniki, Dept. of Civil Engineering, Laboratory of Building Construction and 

Building Physics, 54124 Thessaloniki, Greece.
Tel.: +30 2310 995763, +30 6972096311
E-mail: bikasd@civil.auth.gr 

Panagiotis CHASTAS – Civil engineer and MSc “Environmental protection and sustainable development” graduate, 
School of Civil Engineering of Aristotle University of Thessaloniki (AUTH).
Main research area: Life Cycle Analysis and energy performance in residential buildings.
Address:  Aristotle University of Thessaloniki, Dept. of Civil Engineering, Laboratory of Building Construction and 

Building Physics, 54124 Thessaloniki, Greece.
Tel.: +30 6976500057
E-mail: pchastas@civil.auth.gr