AP04_1.vp


1 Introduction
As known from experimental studies of concrete behav-

iour at room temperature, there is a close correspondence
between compressive strength S and its porosity P. Commonly
this dependence is decreasing function, i.e. strength S de-
creases with porosity P. There are many attempts to express
the relation S � S(P) in an analytical form. It has to be pointed
out, however, that such expressions (as, for example, Bal’shin
relation, Ryshkewitch expression, Schiller law, Hasselman for-
mula – for details see, e.g., [1]) have been mostly derived for
different type of materials.

The present paper is based on the assumption that
changes in porosity P are the main factor effecting changes in
compressive strength S of hardened cement pastes and con-
crete (see, e.g., [2]). The hypothesis is generally accepted,
howerer, some doubts exist [3,4]. Moreover, practically in all
articles cited above the dependence S � S(P) porosity was
modified by a change of w/c ratio. In the present paper all
specimens were prepared at the some w/c coefficient for all
tested samples and the porosity varied due to heat treatment
at different temperature levels. It is therefore interesting
to the dependence of compressive strength S on porosity P in
that case and check, if S � S(P) is at least qualitatively the same
as for the porosity modified by w/c ratio.

2 Experiment

2.1 Composition of concrete
The tested specimens for the whole experimental pro-

gram were made from the concrete mixture, the composition
of which is given in Table 1. Composition corresponds to
the concrete composition applied in real structures (in the
containment of NPP Temelin). The mineral composition of
cement in percentage by weight can be found in [5]. The min-
eral composition of cement in percent per volume is given in
Table 2. Applied starting material is Portland cement with
a small amount of fly ash and traces of slag. The clinker used
for its production was burnt on the optimum content of free
CaO and has a high fraction of alite and C4AF prevailing
over C3A in it. An average size of crystals ranges between
0.025–0.030 mm and a size of belite grains is about 0.20 mm
in average.

2.2 Manufacturing of samples
Mixing of concrete mixtures was carried out in the labora-

tory mixer with the forced circulation. The careful procedure
of loading the ingredients to the mixer and kept time sched-
ule of mixing guaranteed the homogeneous concrete mixture

©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 53

Czech Technical University in Prague Acta Polytechnica Vol. 44  No. 1/2004

Effect of Temperature and Age of
Concrete on Strength – Porosity Relation

T. Zadražil, F. Vodák, O. Kapičková

The compressive strengths of unsealed samples of concrete at the age of 180 days and have been measured at temperatures 20 °C, 300 °C,
600 °C and 900 °C. All of tests were performed for cold material. We compared our results with those obtained in [10] for the same type of
concrete (age 28, resp. 90 days and measured at temperature ranging from 20 °C to 280 °C). Dependencies of compressive strength and
porosity were correlated together and compared for the samples of age 28, 90 and 180 days. Behaviour of concrete of the age 90, resp. 180
days confirms generally accepted hypothesis that with increasing porosity strength of the concrete decreases. It has to be stressed out, howerer,
that concrete samples of the age 28 days exhibit totally opposite dependency.

Keywords: compressive strength, temperature dependency, porosity.

Cement 499 kg

Water 215 kg

Plasticizer
(Ligoplast SF)

4.9 kg

Aggregates

710 kg (0 – 4 mm)

460 kg (8 –16 mm)

530 kg (16 –22 mm)

Table 1: Composition of 1 m3 of concrete mixtures Temelín

CEM I 42.5 Mokrá
Phase clinker composition

C3S 70.0

C2S 11.4

C3A 7.9

C4AF 9.7

Cfree 1.0

Total 100.0

Fraction of components in cement

Clinker 93.3

Gypsum 4.7

Fly ash 1.8

Slag 0.2

Total 100.0

Table 2: Quantitative composition of cements in % by volume



of constant quality in all batches. The tested specimens for
the experimental program were manufactured in two relays.
Attention was paid to the specimens curing. First, the speci-
mens were covered with a polyethylene foil that restrained the
leakage of excessive water from the surface bed of the tested
body. Then, approximately six hours after the manufacturing
ended, the samples including the forms were covered with
a damp fabric and then they were recovered with a polyethyl-
ene foil. The basic specimen of the experimental program was
0.1/0.1/0.4 m beam.

2.3 Heating of specimens
The concrete samples were placed in the high-tempera-

ture furnace BVD 100/KY (temperature range up to 1250 °C)
with the programmable heating and cooling regulator. Tem-
perature increases 100 °C each 15 minutes during the heating
up to final temperature 300 °C, 600 °C, 900 °C, respectively.
Samples were exposed to high temperatures for 2 hours.
Cooling rate was 100 °C per 30 minutes.

Duration of exposure at elevated temperatures (2 hours)
practically guarantees that the samples are heated uniformly
within whole specimen volume. This time period was esti-
mated from solution of heat conductivity equation.
Appropriate input parameters (in particular, thermal con-
ductivity coefficient, resp. specific heat capacity and its
dependency on temperature) were taken from [6].

2.4 Tests of concrete mechanical properties
The compressive strength was determined on the frag-

ments of the beams of the original dimensions 0.1/0.1/0.4 m
after the fracture toughness measurement referred in the
previous paper [11]. All of the tests were performed according
to the method of the Czech National Standard CSN 73 13 18.
The measurements of the compressive strength were per-
formed on 6 specimens for each temperature level.

2.5 Tests of concrete porosity properties
The small fragments of the beam after strength tests were

utilized to determine the concrete texture. Samples were
dried at temperature 105 °C for 4 hours before measurement.
The porosity of hardened cement paste has been measured
by the method of mercury porosimetry using high-pres-
sure porosimeter Micrometrics Auto-Pore 9200 (with pressure
range up to 400 MPa). The porosity was measured on 6 speci-
mens for each temperature level.

3 Results and discussion
Dependence of compressive strength on the temperature

level of heating is shown in Fig. 1. Furthermore, the ratio of
strength value after cooling of the sample and its original
strength value (determined by indoor temperature before
heat pretreatment) is generally referred to be “residual
stregth ratio” [7]. These results are depicted in Fig. 2. The
changes of the porosity with temperature of heating are pre-
sented in Fig. 3. (Each point of these curves corresponds
to the average of six values measured on different speci-
mens heated at the same temperature level). According to
these measurements representative values of strength (S) and
porosity (P) for a given temperature were obtained and suc-
cessively functional dependency S � S(P) was established, see
Fig. 4. The analogical results for concrete at the age of 28 days

54 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 44  No. 1/2004 Czech Technical University in Prague

0

20

40

60

80

0 200 400 600 800 1000

temperature [°C]

c
o

m
p

re
s
s
iv

e
s
tr

e
n

g
th

[M
P

a
]

age 180 days

Fig. 1: Effect of temperature on compressive strength for con-
crete of age 180 days

0

0 2.

0 4.

0 6.

0 8.

1

1 2.

0 200 400 600 800 1000

temperature [°C]

c
o

m
p

re
s
s
iv

e
s
tr

e
g

th
ra

ti
o

age 180 days

Fig. 2: Effect of temperature on compressive strength ratio for
concrete of age 180 days

0

5

10

15

20

25

30

0 200 400 600 800 1000

temperature [°C]

p
o

ro
s
it

y
[%

]

age 180 days

Fig. 3: Effect of temperature on porosity for concrete of age 180
days



and 90 days treated in the temperature range �20 �C–280 °C�
are in Figs. 5–9 [10]. These dependences S � S(P) were com-
pared for different ages of concrete samples (Figs. 4, 8, 9).
Behaviour of concrete samples aged 90 and 180 days (Figs. 4,
9) confirms decreasing compressive strength with the increas-
ing porosity. Samples of the age 28 days behave quite oppo-
sitely, the compressive strength increases with the increasing
porosity (Fig. 8).

Practically in all published papers dependence S � S(P)
is studied at constant (room) temperature and specimens
porosity is modified only by change of w/c ratio. Our atypical
dependence for samples aged 28 days is due to temperature
effect. Usually three competitive factors result from the analy-
sis of temperature influence on properties of concrete:

a) Drying in the temperature range �100 °C–200 °C� in-
creases the strength [7].

b) The increasing content of hydration products occurring in
the temperature range 100 °C to 300 °C (note that the
bound water starts to be released at 180 °C [9]) leads to
an increase of concrete strenght [8]. A probable reason is
larger mobility of water molekules in gaseous phase (as
compared with their mobility in liquids).

©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 55

Czech Technical University in Prague Acta Polytechnica Vol. 44  No. 1/2004

0

20

40

60

80

5 10 15 20 25 30

porosity [%]

c
o

m
p

re
s
s
iv

e
s
tr

e
n

g
th

[M
P

a
]

age 180 days

Fig. 4: Dependence of compressive strength on porosity for con-
crete of age 180 days

40

50

60

70

80

0 50 100 150 200 250 300

temperature [°C]

c
o

m
p

re
s
s
iv

e
s
tr

e
n

g
th

[M
P

a
]

age 28 days

age 90 days

Fig. 5: Effect of temperature on compressive strength for con-
crete of age 28 and 90 days

0.7

0.8

0.9

1

1.1

1.2

0 50 100 150 200 250 300

temperature [°C]

c
o

m
p

re
s
s
iv

e
s
tr

e
g

th
ra

ti
o

age 28 days

age 90 days

Fig. 6: Effect of temperature on compressive strength ratio for
concrete of age 28 and 90 days

10

12

14

16

18

20

0 50 100 150 200 250 300

temperature [°C]

p
o

ro
s
it

y
[%

]

age 28 days

age 90 days

Fig. 7: Effect of temperature on porosity for concrete of age 28
and 90 days

45

50

55

60

65

70

75

80

12 14 16 18 20

porosity [%]

c
o

m
p

re
s
s
iv

e
s
tr

e
n

g
th

[M
P

a
]

age 28 days

Fig. 8: Dependence of compressive strength on porosity for con-
crete of age 28 days



c) Microcracking due mainly to thermal incompatibility of
the hardened cement paste and aggregate which increases
porosity and decreases strength [7]. This process takes
place throughout whole temperature interval.

From presented measurements may be deduced that re-
sulting balance of these three influences essentially depends
on the age of concrete. Increasing content of hydration prod-
ucts plays dominant role, especially for concrete at the age of
28 days (with relatively large volume of unhydrated cement)
due to intensifying hydration with temperature (between
�100 °C–300 °C�). This process causes similar behaviour of
strength as certain curing treatments (so-called steam curing).
These facts result in extraordinary dependence of strength
on porosity (Fig. 8), which behaves as increasing function,
contrary to original hypothesis. On the other hand, hydration
processes are practically terminated in concretes at the age
of 90 days and the functional dependence S � S(P) (Fig. 9)
corresponds to initial hypothesis, since the major role is
now played by microcracking. Additional „minihydration“ is
caused mostly by water molecules of relatively high kinetic
energies released at temperatures above 250 °C. This phe-
nomenon, which leads to low increasing of the strength and
decreasing of the porosity (see Figs. 5 and 7), is again in good
agreement with initial hypothesis. The results for the concrete
at the age 180 days are quite problemless. The function
S � S(T) decreases, the function P � P(T) increases and the
dependency S � S(P) is the decreasing function. We may sup-
pose that all significant hydration processes are finished at
this age and changes of porosity and strength are influence
only by microcracing.

Acknowledgement
This work was partially supported by the MSMT CR (con-

tract No J304-098:210000020).

References
[1] Taylor H. F. W.: Cement Chemistry. London: Thomas Tel-

ford Publ., 1997.

[2] Odler I., Rossler M.: “Investigations on the Relationship
between Porosity, Structure and Strength of Hydrated
Portland Cement Pastes I a II.” Cem. Concrete Res.,
Vol. 15 (1985), p. 320–330, 401–410.

[3] Jambor J.: “Influence of Phase Composition of Hard-
ened Binder Pastes on its Pore Structure and Porosity.”
In: Pore Structure and Properties of Materials (Editor: S.
Modrý). Prague: Academia, 1973, p. D75–D95.

[4] Fagerlund G.: Strength and Porosity of Concrete. In: Pore
Structure and Properties of Materials (Editor: S. Modrý).
Prague: Academia, 1973, p. D57–D73.

[5] Vydra V., Vodák F., Kapičková O., Hošková Š.: “Effect
of Temperature on Porosity of Concrete for Nuklear-
-safety Structures.” Cem. Concr. Res., Vol. 301 (2001),
p. 1023–1026.

[6] Vodák F. et al: “Tables of Physical Properties of Con-
cretes for Nuclear-safety Structures.” In: CTU Reports 4
(2000) (Editor: F.Vodák). Prague: CTU Publ. House,
2000.

[7] Bažant Z. P., Kaplan M. F.: Concrete at High Temperatures.
Essex: Longman, 1996.

[8] Jambor J.: “Porosity, Pore Structure and Strength of
Cementeous Composites.” Staveb. čas., Vol. 33 (1985),
p. 743–764.

[9] Komarovskij A. N.: Design of Nuclear Plants. Moscow:
Atomizdat, 1965.

[10] Hošková Š., Kapičková O., Trtík K., Vodák F.: Experi-
mental study of relation among elevated temperature exposure,
strength and structure of concrete employed in contaiment
of NPP Temelin. In: Research activities of Physical De-
partments of Civil Engineering Faculties in the Czech
and Slovak Republics. (Eds: L. Pazdera and M. Kořen-
ská). Brno, 2001, p. 25–28.

[11] Zadražil T., Vodák F., Trtík K.: “Vliv teploty na pev-
nost betonu užitého při stavbě kontejnmentu jaderné
elektrárny Temelín.” Stavební obzor, Vol. 9 (2003),
p. 272–274.

Ing. Tomáš Zadražil
phone: +420 224 354 693
e-mail: xzadrazt@stu.fsv.cvut.cz

Prof. František Vodák, DrSc.
phone: +420 224 353 886
e-mail: vodak@fsv.cvut.cz

RNDr. Olga Kapičková, CSc.
phone: +420 224 354 696
e-mail: kapickov@fsv.cvut.cz

Department of Physic

Czech Technical University in Prague
Faculty of Civil Engineering
Thákurova 7
166 29 Praha 6, Czech Republic

56 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 44  No. 1/2004 Czech Technical University in Prague

50

55

60

65

70

13 14 15 16 17

porosity [%]

c
o

m
p

re
s
s
iv

e
s
tr

e
n

g
th

[M
P

a
]

age 90 days

Fig. 9: Dependence of compressive strength on porosity for con-
crete of age 90 days