Acta Polytechnica


doi:10.14311/AP.2017.57.0159
Acta Polytechnica 57(3):159–166, 2017 © Czech Technical University in Prague, 2017

available online at http://ojs.cvut.cz/ojs/index.php/ap

EVALUATION OF THE APPLICATION OF A THERMAL
INSULATION SYSTEM: IN-SITU COMPARISON OF SEASONAL

AND DAILY CLIMATIC FLUCTUATIONS

Jan Fořta, ∗, Pavel Beranb, Petr Konvalinkaa, Zbyšek Pavlíka,
Robert Černýa

a Czech Technical University in Prague, Faculty of Civil Engineering, Thákurova 7, 166 29 Prague, Czech
Republic

b Academy of Sciences of the Czech Republic, Institute of Theoretical and Applied Mechanics, Centre of
Excellence Telč / ARCCHIP, Batelovská 485-486, 588 56 Telč, Czech Republic

∗ corresponding author: jan.fort.1@fsv.cvut.cz

Abstract. The current outdated state of many institutional and administrative buildings in the
EU region poses a significant burden from the energy sustainability point of view. According to the
contemporary EU requirements on the energy efficiency of buildings maintenance, an evaluation of
performed improvements is essential for the assessment of expended investments. This paper describes
the effect of building envelope reconstruction works consisting in the installation of a thermal insulation
system. Here, a long-term continuous monitoring is used for the extensive assessment of the seasonal
and daily temperature and relative humidity fluctuations. The obtained results include temperature
and relative humidity profiles in the wall cross-section as a response to the changing exterior climatic
conditions. The analysis of measured data reveals substantial improvements in thermal stability of the
analyzed wall during temperature peaks. While the indoor temperatures exceeding 28 °C are recorded
during summer before application of the thermal insulation layer, the thermal stability of the indoor
environment is distinctly upgraded after performed improvements. Based on the complex long-term
monitoring, a relevant experience is gained for the future work on energy sustainability and fulfilment
of the EU directives.

Keywords: in-situ monitoring; temperature; relative humidity; thermal insulation; energy sustainabil-
ity; seasonal fluctuations.

1. Introduction
Building maintenance represents a substantial part
in the total worldwide energy consumption. Accord-
ing to numerous studies, buildings pose a large and
unexploited source for reduction of carbon dioxide
emissions as well as potential energy savings. To be
specific, buildings present the third most demanding
sector after industry and transportation from the en-
vironmental point of view. Particularly, the heating
and cooling requirements are responsible for almost
40 % of the total energy consumed by the building
sector [1]. Within the sustainable development, the
new European directives are aimed at the better en-
ergy performance of buildings in all involved countries.
According to the 2010/31/EU Directive, the public ad-
ministration and institution buildings are considered
as leading sector for making progress in the energy ef-
ficiency of buildings [2]. Therefore, all member states
are required to minimize energy demands related to
the building maintenance. Moreover, for the new pub-
lic administration and institution buildings, it will
be obligatory to fulfil directive standards of a nearly
zero energy building [3]. These commitments should
be precisely defined at the national level, due to the
exact definition of the nearly zero energy building. Ac-
cording to the provided 2012/27/EU Directive, proper

strategies of investments for building renovations to
increase modernization rate of current buildings are
defined [4].
Notwithstanding, many institutional and public

administration buildings in the Czech Republic are
substantially outdated, especially from the thermal
performance point of view. The buildings designed
in previous decades, in many cases, do not provide
stable ambient conditions, particularly during sea-
sonal temperature fluctuations. They also do not
meet the requirements on thermal comfort for inhabi-
tants. Moreover, regarding the efforts to decrease the
energy consumption, these outdated buildings with
poor thermal performance require an installation of
additional heating/cooling devices [5]. This common
temporary solution is beneficial for managing the ther-
mal comfort, but it unfortunately leads to an energy
demanding and noisy service. Utilization of portable
A/C devices does not provide an adequate solution
from the long-term perspective.

A proper understanding of the relationship between
the exterior climatic conditions and the quality of
the indoor environment is based on the monitoring
of temperature, relative humidity, illumination, air
quality, etc. [6]. The influence of the utilization of
various monitoring techniques on energy reduction

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J. Fořt, P. Beran, P. Konvalinka et al. Acta Polytechnica

Figure 1. Photo of the studied building: before the application of thermal insulation (left); after reconstruction
works (right).

solution was studied by Batista et al. [7]. Here, a
decision based mainly on a building simulation is not
recommended. The explanation of this conclusion lies
in the differences between building plans and the real
state of building including faults occurred during the
construction process, which can significantly affect
the obtained data.
The research methods can be categorized as qual-

itative and quantitative [8]. A spot or long-term
monitoring methods can be distinguished in order
to evaluate the indoor thermal comfort as well as
the environment quality from the perspective of the
quantitative methods [9]. From the environmental
viewpoint, the total energy consumption related to
the certain time interval is probably the mostly used
evaluation method [10]. The life cycle assessment,
primary consumption or carbon emissions equivalent
are extensively used especially in relation to the life
cycle of the building or particular materials [11]. The
low thermal resistance of external walls of an out-
dated building is mostly fixed by the application of an
exterior insulation system, which ensures substantial
improvements of the thermal comfort as well as the
energy sustainability. However, besides the accom-
plishment of the EU directives aimed at the nearly
zero energy buildings, appropriate ambient climatic
conditions and requirements must be ensured for the
convenience of building residents [12].
Although modern energy efficiency measures are

more less concentrated to the energy consumption,
Mikulčioniene et al. [13] presented a multicriterial
method to promote building retrofitting. Indoor ther-
mal comfort can be perceived as the one of the most im-
portant factors and achievement of the indoor thermal
comfort for building occupants represents a substantial
objective, which should be satisfied in order to provide
appropriate working and health conditions [14].
According to the study of Zhang et al. [15], some

differences can be found in the terms of ideal indoor
temperature. In China, the indoor comfort zone is
around 21.7 °C, while the ideal indoor temperature
in Europe is 23.4 °C. Therefore, many studies were
proposed in order to optimize the indoor thermal
comfort, natural ventilation, employment of the HVAC

system. However, the maintenance of the ambient
conditions directly affects the energy need for the
heating or cooling purposes.
Importance of the maintenance of ambient air is

connected not only with comfort of building occupants,
but also with health issues. The negative health con-
sequences of the undesirable indoor conditions, such
as overheating and low or high relative humidity, con-
sist in irritation of eyes, dryness of skin and throat,
reduced work efficiency and respiratory problems [16].
Moreover, the higher risk of condensation may cause
material defacement and proliferation of microorgan-
isms [17]. The risks of water vapour condensation,
frost damage and mould growth should be considered
in all renovation and building insulation works [18].
Within this study, an outdated institutional build-

ing from 1960s is subjected to a long-term temperature
and relative humidity monitoring beginning in 2012.
Based on the preliminary data, overheating during the
summer period and substantial heat losses during the
winter period resulted in a high energy consumption.
The installation of the additional external insulation
system was done in autumn/winter 2013, in order to
improve the indoor environment quality for building
inhabitants and decrease of sensitivity of the building
to the exterior temperature fluctuations. The perfor-
mance of the applied insulation systems is evaluated
on the basis of the comparison of the long-term moni-
toring data before and after conducted reconstruction
works.

2. Experimental
2.1. Studied building
The investigations were done on the institutional build-
ing built in 1960s, located in the north-west suburb
part of Prague, the capital of the Czech Republic.
The studied building is composed of reinforced con-
crete column structure having 3 stories. The exterior
envelope is constructed from the hung facade slabs
formed of steel frames, aluminous window frames,
glass, and insulation boards. Part of the envelope is
built from cavity brick blocks provided on the surface
by cement-lime plaster.

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Figure 2. Scheme of sensors placement.

Element U-value [W/m2K]
Initial state Final state

Facade 1.12 0.29
Roof 0.86 0.15
Window 2.40 1.21
Door 1.72 1.22

Table 1. Summarized description of initial and final
state of studied building.

The additional exterior contact thermal insula-
tion system was applied during autumn 2013 (Oc-
tober–December). It consists of adhesive mortar JUB
JUBIZOL (polymer-modified micro-reinforced cement
mortar mixture) used for gluing insulation boards and,
as a brown coat, expanded polystyrene board EPS
PERIMETR having a thickness of 150 mm, alkali resis-
tant reinforcing mesh, acrylic base paint UNIGRUND
applied under thin-film plasters and water vapour
permeable siloxane plaster UNISIL G with fungicidal
additives. The insulation boards are fastened by fix-
ing plastic/metal anchors. The outside view of the
reconstructed building envelope and applied thermal
insulation system is given in Figure 1.
The monitoring of the hygrothermal performance

was done for the part of the envelope formed by cavity
brick blocks and exterior and interior plasters. This
part of the building facade is considered to be the
main cause of the heat losses of the building. Here, the
material durability problems are also expected. New
windows with insulating glazing and frames together
with new insulated door and gates were placed in
order to improve the thermal stability of the building.
Summarized information of the initial state of the
building is described in Table 1.

2.2. HVAC system
Studied building is not equipped with its own heat
source, but is connected to the central heat supply
system. The time heat regulation is installed only for
the administrative part of the building and the rest is
equipped only with thermostatic valves. There is no
regulating fitting on the return pipes. Running of the

heating system is ensured by suitable pumps with a
continuous regulation.

However, due to the size of the object, it is possible
to consider the heating system at the main points and
meeting the requirements of the Decree No. 194/2007.
However, the regulation of hydraulic regulation is not
optimal. The thermal insulation of heat distribution
pipes is in a good visual condition and energy losses
related to the material conditions are approximately
7 %. The object is not equipped by any ventilation
or A/C devices; only portable A/C devices are partly
used. Ventilation is managed only naturally by open-
ing windows.

2.3. Sensors placing
The tested structure was continuously monitored
by relative humidity and temperature measure-
ments. Here, the combined mini-sensors, produced
by Ahlborn (Germany), which allow a measurement
of the relative humidity in the range of humidity of
5–98 % and the accuracy within ±2 %, the resistance
temperature sensors have the accuracy of ±0.4 °C in
the temperature range of −20 to 0 °C and ±0.1 °C in
range of 0–70 °C were used. The particular sensors
were connected with the measuring unit that was con-
trolled by a computer. The data were continuously
collected, whereas the experiment was operated by
a remote computer station. In total, 16 measuring
channels were installed. The measurement runs from
April 2012 and still continues. The sensor placement
is shown in Figure 2. Dimensions used for the sensor
placement description are stated in mm.
Together with the monitoring of temperature and

relative humidity profiles, the simultaneous measure-
ment of the exterior climatic conditions was done by
using the weather station Fiedler-Mágr (Czech Re-
public) with 16 recording channels. The following
sensors were applied: W2t for the measurement of
wind velocity and direction (heated version), RV12 for
the relative humidity and temperature measurement,
psychrometer SR02 with a collecting board of 200 cm2
and with a distinction of 0.2 mm, and pyranometer
for the measurement of global solar radiation. The
weather station was placed on the roof of the studied
building.

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J. Fořt, P. Beran, P. Konvalinka et al. Acta Polytechnica

Figure 3. Average monthly climatic data.

3. Results and discussion
The exterior climatic conditions, namely the monthly
average temperatures and the monthly average relative
humidity, are shown in Figure 3. Here, an overview
and a year-by-year comparison show only minor differ-
ences between the average values of monitored outdoor
conditions. In general, the average monthly temper-
ature was slightly higher in 2014 compared to 2013,
which was more distinct during spring and autumn.

3.1. Seasonal fluctuations
3.1.1. Temperature profiles
The temperature profiles in selected representative
days from spring, summer, autumn and winter are
presented in Figure 4, where distinct differences can be
observed. Temperature profiles were determined for
selected days, which allows year-to-year comparison
based on the similar day weather conditions. Days se-
lected within the evaluation represent critical exterior
conditions typical for the particular period, for exam-
ple, high temperature during summer and low during
winter period. This selection allows an assessment of
the applied insulation layer by temperature profiles,
which are typical for certain period and represent ex-
terior climate loads. For the day used for description
of 2012, the corresponding days with very similar tem-
perature and relative humidity were identified and
further analysed.

The conditions before application of the insulation
system were unpleasant, especially for the building
occupants, as an apparent thermal discomfort (dur-
ing summer and autumn season) was noted. To be
specific, temperature during summer reached almost
28 °C and in autumn dropped to 20 °C. In terms of
ideal indoor temperature [15], this unsatisfactory state
requires a remediation. The undesirable indoor en-
vironment could certainly affect the work efficiency
and health of building occupants in a negative way.

According to the temperature profiles from 2013 (be-
fore reconstruction) plotted in Figure 4, it is possible
to conclude that the building envelope suffered from
the changing climatic conditions and the thermal sta-
bility was considerably poor. However, temperature
profiles from the summer period referred to build-
ing overheating problems and a necessity to apply
additional cooling devices [19]. From the perspec-
tive of building occupants, the interior temperature
of almost 28 °C was very unpleasant and worsened
the quality of the working environment [9]. It was
revealed that the interior temperature remained high
due to the heat solar gains through the hung façade
system. In the light of these findings, the applica-
tion of external insulation system was urgent in order
to improve the thermal performance of the outdated
building envelope [20]. The importance of the con-
sideration of the day temperature peak was studied
by [21]. Here, continuous monitoring was used in
order to estimate the time of the temperature peak
of several buildings. Obtained results point to the
substantial influence of the building orientation and
consequent differences between energy released during
various day periods or seasons. A complex assessment
of a campus building in France, including different
aspects, allowed to overcome the dilemma between
the comfort and energy efficiency. An employment of
a PVM (predicted mean vote) and a PPD (predicted
percentage of dissatisfied) revealed, in some cases,
situations, when certain phenomena induce thermal
discomfort and an increased energy consumption at
the same time [22]. Conducted research focused on
the influence of seasonal variations on the indoor tem-
perature clarified fluctuation. Authors concluded that
neutral temperature is higher in autumn compared
to spring, due to a higher number of used fans and
opened windows. Thus, occupants feel cooler at the
same temperature in autumn, as a result of higher
indoor air velocity.

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Figure 4. Seasonal comparison of temperature profiles.

Figure 5. Seasonal comparison of relative humidity profiles.

The temperature profiles measured after the instal-
lation of the thermal insulation layer show a significant
effect of the applied layer towards energy sustainabil-
ity and better thermal stability. The insulation layer,
formed by a mineral wool, substantially reduced the
negative effect of temperature fluctuations on the
interior temperature response. Compared to the tem-
perature data before reconstruction, the temperature
profiles in the load bearing structure exhibited a lower
temperature gradient. This fact can be assigned to the
significant improvement of the thermal performance
of the building envelope. In general, the average in-
door temperature, about 26.5 °C during the summer
period, was decreased to the more comfortable 23.2 °C.
Moreover, costs related to the building maintenance,
particularly heating, were substantially reduced – ap-
proximately by half .

3.1.2. Relative humidity profiles
The representative relative humidity profiles in the
wall cross-section obtained during winter, spring, sum-
mer and autumn are given in Figure 5. The obtained
values referred to a low level of the indoor relative
humidity, which could have a negative influence on
occupants’ health (eye irritation, dry throat) and work
efficiency, especially during winter period when the
RH level drops below 30 %. However, for the rest of
the year, relative humidity values are kept in the com-
fort zone and the ambient condition are satisfactory
for building inhabitants. From this point of view, the
application of the thermal insulation layer did not
have any substantial effect on indoor relative humid-
ity levels. Here, only minor changes were obtained
within year-to-year comparison, for example, a slight
decrease of the indoor air humidity was observed. The

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J. Fořt, P. Beran, P. Konvalinka et al. Acta Polytechnica

Figure 6. Daily comparison of temperature profiles.

Figure 7. Daily comparison of relative humidity profiles.

effect of the application of thermal insulation layers
on the indoor relative humidity was studied, e.g., by
Korjenic et al. [23] with similar conclusions. This
problem is widely analysed in modern low energy and
passive houses, where the application of insulation
polystyrene layer has a negative effect on the rela-
tive humidity level. Here, the air recuperation is the
mostly used way to moderate the relative humidity
level and keep it in the desired range in order to elim-
inate health risks related to the low level of relative
humidity. The low level of relative humidity measured
during 07.2014 can be attributed to the use of the
portable A/C device in order to reduce the increased
indoor temperature.

3.2. Daily temperature fluctuations
Diurnal changes in the exterior conditions, especially
during certain periods such as sunny springs days,
when nocturnal temperature often drops below the
zero, represent considerable burden for the building

envelope, especially due to the possible risk of wa-
ter vapour condensation. Moreover, daily temper-
ature variations in the cross section wall refer to
the unstable and undesirable conditions. A low ther-
mal performance of the building envelope is respon-
sible for the higher energy consumption required for
maintenance of the indoor thermal comfort. Fur-
thermore, a low thermal inertia plays an important
role during temperature peaks and significantly af-
fects the quality of the interior climate for building
occupants. The employment of additional cooling
devices is unfortunately accompanied with higher
energy demands [24]. Also, it is not always pos-
sible to use these devices due to space limitations
and, last but not least, the operational noise of
portable cooling devices substantially limits their uti-
lization on a daily basis. It should be noted, that
the application of the central A/C solution is not
widespread in the Czech Republic in institutional
buildings.

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vol. 57 no. 3/2017 Evaluation of the Application of a Thermal Insulation system

In the measurements performed in this paper, the
negative effect of the daily temperature fluctuations
was successfully minimized by the application of the
mineral wool thermal insulation layer. The overheat-
ing of the building was substantially reduced, as it is
documented in Figure 6. In the light of these findings,
one can conclude that the indoor thermal comfort was
significantly improved and occupants did not suffer
from the high temperatures. In this case, days with
high temperature values were submitted for evaluation
of the influence of applied insulation system. For this
purposes, days with temperature about 34.5 °C (14:00)
were selected in order to access maximal temperature
load induced by the exterior weather conditions, which
significantly affect the ambient conditions. The rea-
son for choosing the summer period is based on the
problems related to a room overheating. During the
winter period, almost no changes are observed because
temperature profiles are strongly connected with the
building heating, and the changes are compensated
by the increased energy consumption.
The daily variation of the relative humidity level

was negligible, as it is illustrated in Figure 7. In order
to access diurnal relative humidity fluctuation, the
typical winter days with 78.6 % RH were used for this
comparison.

The application of the thermal insulation layer did
not affect the relative humidity profiles in the wall
cross-section, however, lower values of the relative
humidity poses a possible health risk related to the
building occupants as was stated above. Notwith-
standing, the diurnal fluctuation are only minor and
from this point of view, no significant changes oc-
curred.

4. Conclusions
The evaluation of the functionality of the thermal in-
sulation system applied on the outdated institutional
building from 1960s proved its beneficial influence on
the thermal stability. Thanks to the installed sen-
sors in different depths, it was possible to perform
a continuous monitoring of temperature and relative
humidity fluctuations related to the changing exterior
climatic conditions. A detailed analysis of the pre-
reconstruction conditions in the building envelope al-
lowed the identification of fundamental factors, which
substantially influenced the obtained results and the
previous low thermal performance. Together with the
seasonal variations, the diurnal fluctuations of studied
parameters were also identified as critical factors for
the seasonal and daily overheating. The comparison
of the temperature and relative humidity profiles in
the wall cross-section between the pre-reconstruction
state and after reconstruction confirmed substantial
improvements achieved in the field of the thermal
stability, resulting in more comfortable conditions for
building occupants. The obtained results also showed
decreased energy consumption demands.

Acknowledgements
This research has been supported by the Czech Science
Foundation, under project No GBP105/12/G059.

References
[1] IEA, CO2 Emissions from Fuel Combustion.
International Energy Agency. Paris, France, p. 512, 2008.

[2] EU Commission, Commission Delegated Regulation
(EU) No. 244/2012 supplementing Directive
2010/31/EU of the European Parliament and of the
Council on the energy performance of buildings. Official
Journal of the European Union, 2012.

[3] Berry, S., Whaley, D., Davidson, S., Saman, W.: Near
zero energy homes – What do user think?, Energ.
Policy, 73, 2014, p. 127-137,
doi:doi.org/10.1016/j.enpol.2014.05.011

[4] Ascione, F., Bianco, N., Bottcher, O., Kaltenbrunner,
R., Vanoli, G.P.: Net zero-energy buildings in Germany:
Design, model calibration and lessons learned from a
case-study in Berlin. Energy Build., 133, 2016, p.
688-710. doi:10.1016/j.enbuild.2016.10.019

[5] Carbonara, G.: Energy efficiency as a protection tool,
Energy Build. 95, 2015, p. 9–12,
doi:10.1016/j.enbuild.2014.12.052

[6] Balaras, C.A.: European residential buildings and
empirical assessment of the Hellenic building stock,
energy consumption, emissions and potential energy
savings, Build. Environ., 42, 2007, p. 1298-1314,
doi:10.1016/j.buildenv.2005.11.001

[7] Batista, A. P., Freitas, M. A., Jota, F. G.: Evaluation
and improvement of the energy performance of a
building´s equipment and subsystems through
continuous monitoring. Energy Build., 75, 2014, p.
368-381, doi:10.1016/j.enbuild.2014.02.029

[8] Guerra-Santin, O., Tweed, Ch. A.: In-use monitoring
of buildings: An overview of data collection methods.
Energy Build., 93, 2015, p. 189-207,
doi:10.1016/j.enbuild.2015.02.042

[9] Citherlet, S., Hand, J.: Assessing energy, lighting,
room acoustic, occupant comfort and environmental
impacts performance of building with a single
simulation program. Build. Environ., 37, 2002, p.
845-856. doi:10.1016/S0360-1323(02)00044-6

[10] Berry, S., Davidson, K.: Zero energy homes – Are
they economically viable? Energ. Policy, 85, 2015, p.
12-21, doi: 10.1016/j.enpol.2015.05.009

[11] Chantrelle, F.P., Lahmidi, H., Keilholz, W., El
Mankibi, M., Michel, P.: Development of a multicriteria
tool for optimizing the renovation of buildings, Appl.
Energy, 88, 2011, p. 1386–1394,
doi:10.1016/j.apenergy.2010.10.002

[12] Moatassem, A., El-Rayes, K., Liu, L.: Economic and
GHG Emission Analysis of Implementing Sustainable
Measures in Existing Public Buildings, J. Performance
Constr. Facilit., Vol. 30, No. 6, 2016, p. 165-174.
doi:10.1061/(ASCE)CF.1943-5509.0000911

[13] Miulčioniene, R., Martinaitis, V., Keras, E.:
Evaluation of energy efficinecy measures sustainability
by decision tree method. Energy Build., 76, 2014, p.
64-71, doi:10.1016/j.enbuild.2014.02.048.

165

http://dx.doi.org/doi.org/10.1016/j.enpol.2014.05.011
http://dx.doi.org/10.1016/j.enbuild.2016.10.019
http://dx.doi.org/10.1016/j.enbuild.2014.12.052
http://dx.doi.org/10.1016/j.buildenv.2005.11.001
http://dx.doi.org/10.1016/j.enbuild.2014.02.029
http://dx.doi.org/10.1016/j.enbuild.2015.02.042
http://dx.doi.org/10.1016/S0360-1323(02)00044-6
http://dx.doi.org/ 10.1016/j.enpol.2015.05.009
http://dx.doi.org/10.1016/j.apenergy.2010.10.002
http://dx.doi.org/10.1061/(ASCE)CF.1943-5509.0000911
http://dx.doi.org/10.1016/j.enbuild.2014.02.048. 


J. Fořt, P. Beran, P. Konvalinka et al. Acta Polytechnica

[14] Ascione, F., Bianco, N., De Masi, R. F., Vanoli, G.
P.: Rehabilitation of the building envelopes of hospitals:
achievable energy savings and microclimatic control on
varying the HVAC systems in Mediterranean climates.
Energy Build., 60, 2013, p. 125-138.
doi:10.1016/j.enbuild.2013.01.021

[15] Zhang, N., Cao, B., Wang, Z., Zhu, Y., lion, B.: A
comparison of winter indoor thermal envinronment and
thermla comfort between regions in Europe, North
America and Asia, Build. Environ., 117, 2017, p.
208-217, doi:doi.org/10.1016/j.buildenv.2017.03.006

[16] Zhang, H„ Gong, N., Zhao, L.: Indirect effects of
air-conditioning relative humidity of hospital buildings
in summer on human health. Journal of Central South
University (Science and Technology), 43, 2012, p.
3727–3733.

[17] Dall´O, G., Sarto, L., Galante, A., Pasetti, G.:
Comparison between predicted and actual energy
performance for winter heating in high-performance
residential buildings in the Lombardy region (Italy).
Energy Build., 47, 2012, p. 247-253.
doi:10.1016/j.enbuild.2011.11.046

[18] Toftum, J., Jorgensen, A. S., Fanger, P. O.: Upper
limits for indoor air humidity to avoid uncomfortably
humid skin. Energy Build., 28, 1998, p. 1-13.
doi:10.1016/S0378-7788(97)00017-0.

[19] Brunner, S., Simmler, H.: In-situ performance
assessment of vacuum insulation panels in a flat roof

construction. Vacuum, 82, 2008, p. 700-707,
doi:10.1016/j.vacuum.2007.10.016

[20] Kruger, E., Givoni, B.: Thermal monitoring and
indoor temperature predictions in a passive solar
building in an arid environment. Build. Environ., 43,
2008, p. 1792-1804. doi:10.1016/j.buildenv.2007.10.019

[21] Sham, J. F. C., Memon, S. A., Lo, T. Y.:
Application of continuous surface temperature
monitoring technique for investigation of nocturnal
sensible heat release characteristics by building fabrics
in Hong Kong, Energy Build., 58, 2013, p. 1-10,
doi:10.1016/j.enbuild.2012.11.025

[22] Allab, Y., Pellegrino, M., Guo, X., Nefzaoui, E.,
Kindinis, A.: Energy and comfort assessment in
education building: Case study in a French university
campus, energy Build., 143, 2017, p. 202-219,
doi:10.1016/j.enbuild.2016.11.028

[23] Korjenic, A.; Teblick, H.; Bednar, T.: Increasing the
thermal indoor humidity levels in buildings with
ventilation systems: Simulation aided design in case of
passive houses. Building Simul., 2010, p. 295-310,
doi:10.1007/s12273-010-0015-2

[24] Andersen, R., Fabi, V., Corgnati, S.: Predicted and
actual indoor environmental quality: verification of
occupants’ behaviour models in residential buildings.
Energy Build. 127, 2016, p. 110–115.
doi:10.1016/j.enbuild.2016.05.074

166

http://dx.doi.org/10.1016/j.enbuild.2013.01.021
http://dx.doi.org/doi.org/10.1016/j.buildenv.2017.03.006
http://dx.doi.org/10.1016/j.enbuild.2011.11.046
http://dx.doi.org/10.1016/S0378-7788(97)00017-0. 
http://dx.doi.org/10.1016/j.vacuum.2007.10.016
http://dx.doi.org/10.1016/j.buildenv.2007.10.019
http://dx.doi.org/10.1016/j.enbuild.2012.11.025
http://dx.doi.org/10.1016/j.enbuild.2016.11.028
http://dx.doi.org/10.1007/s12273-010-0015-2
http://dx.doi.org/10.1016/j.enbuild.2016.05.074

	Acta Polytechnica 57(3):159–166, 2017
	1 Introduction
	2 Experimental
	2.1 Studied building
	2.2 HVAC system
	2.3 Sensors placing

	3 Results and discussion
	3.1 Seasonal fluctuations
	3.1.1 Temperature profiles
	3.1.2 Relative humidity profiles

	3.2 Daily temperature fluctuations

	4 Conclusions
	Acknowledgements
	References