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Engineering, Technology & Applied Science Research Vol. 11, No. 2, 2021, 6974-6978 6974 
 

www.etasr.com Boukendakdji et al.: The Effects of Steam-Curing on the Properties of Concrete 

 

The Effects of Steam-Curing on the Properties of 

Concrete 
 

Mustapha Boukendakdji 

College of Engineering 
University of Hail 
Hail, Saudi Arabia 

m.boukendakdji@uoh.edu.sa 

Mabrouk Touahmia  

College of Engineering 
University of Hail 
Hail, Saudi Arabia 

m.touahmia@uoh.edu.sa 

Belkacem Achour  

College of Engineering 
University of Hail 
Hail, Saudi Arabia 

b.achour@uoh.edu.sa 

Ghazi Albaqawy  

College of Engineering 
University of Hail 
Hail, Saudi Arabia 

g.albaqawy@uoh.edu.sa 

Mohamed Abdelhafez 

College of Engineering 

University of Hail 
Hail, Saudi Arabia 

mo.abdelhafez@uoh.edu.sa 

Khaled Elkhayat 

College of Engineering 

University of Hail 
Hail, Saudi Arabia 

m.elkhayat@uoh.edu.sa 

Emad Noaime  

College of Engineering 

University of Hail 
Hail, Saudi Arabia 

e.noaime@uoh.edu.sa 
 

 

Abstract-Worldwide, concrete is the most preferred construction 
material. The steam curing method is favored when there is a 

need for accelerating strength. This paper presents the study of 

the compressive and flexural tensile strength of concrete 

subjected to eight different steam cures. In addition, the stress-

strain curve and the modulus of elasticity were determined at the 

age of 28 days. The compressive strength test results show that 
after treatment, strength increases with concrete maturity. A 

cycle with a pre-heating period gives better results than a cycle 

without a pre-heating period. The longer the duration of the 

maximum temperature period, the lower the strength drop 

compared to the control concrete. The best results were obtained 

for concrete treated according to the following cycle: a 3-hour 

pre-heating period at 20
o
C, a 2-hour increase of temperature 

from 20 to 70
o
C, and a 3 hour of maximum temperature of 70

o
C. 

Keywords-steam curing; compressive strength; flexural tensile 

strength; modulus of elasticity; maturity   

I. INTRODUCTION  

Concrete is extensively used as a construction material and, 
globally, it is the second highest consumed material [1]. 
Ordinary Portland Cement (OPC) is usually used as the 
primary binder to make concrete and is one of the most energy-
intensive construction materials. The primary reason for using 
steam in the curing of concrete is to produce high early 
strength, which is very desirable to the manufacturers of 
precast and pre-stressed concrete units [2]. There are many 
advantages in steam curing such as the production of concrete 
with high early strength, short production cycle, and superior 
economic benefits [3, 4]. The steam curing process includes the 
following four phases: the delay period, the isothermal period, 
the heating period, and the cooling period [5]. Heat treatment 
has been used to accelerate the development of the strength of 
concrete products, such as bricks and small concrete elements. 
By increasing temperature and duration, the strength of 
concrete is increased [6]. Authors in [7] showed that 85°C is 

the optimum temperature in order to obtain high early strength. 
Authors in [8] demonstrated the improved early-age strength of 
high performance concrete through steam curing. Authors in 
[9] showed that as the temperature increases, the compressive 
and flexural strength of concrete at early age increase. Authors 
in [5] reported that 65% of the strength of the control concrete 
at 28 days was obtained by thermal treatment within 24h after 
mixing. Similar results have also been reported in [6,10, 11]. 
The same results have been obtained for concrete with 
superplasticizers [12] and slag [5]. In order to obtain good final 
strength, it is not advisable to immediately heat the concrete. 
The faster the speed of temperature rising, the more the final 
strength of the treated concrete is weakened. Authors in [9] 
showed that the increase in temperature has significant impact 
on the compressive and flexural tensile strength of concrete. 
However, there is no effect on strength when hard concrete is 
exposed to 6-hour fire at 1000°C [13]. Authors in [5, 14] 
reported that the effect of heat treatment on the modulus of 
elasticity is the same as that on strength. Authors in [14] 
reported that the optimum rate of heating and preset period 
should be selected based on the maximum chamber 
temperature in use in order to secure the desired results. There 
was enhancement in the early compressive strength due to the 
effect of steam curing, however the delay period before steam 
curing is very essential for the early strength gain [2, 15]. 
Authors in [5] showed that the reduction in shrinkage of steam-
cured concrete when compared to normal cured concrete is 
about 10%. Finally, steaming leads to a reduction of 20 to 30% 
of the creep compared to the same concrete, cured at room 
temperature and loaded with equal stress/strength ratio [16]. 
This reduction in creep has been confirmed by [5, 12].  

II. MATERIALS AND EXPERIMENTAL DETAILS 

Nine concrete mixtures were tested in this program. The 
concrete had an OPC content of 350kg/m

3
. The total aggregate/ 

cement ratio was 5.41, the gravel/sand ratio was 1.61, and the 

Corresponding author: Mustapha Boukendakdji



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water/cement ratio was 0.57. For all the mixtures, the coarse 
and fine aggregates were weighed in dry room conditions. The 
control OPC concrete was designed to develop a 28-day cube 
compressive strength of 35MPa. All the concrete mixtures were 
mixed for 2min in a laboratory mixer. All molded specimens 
were cured for 24h under wet hessian, then were demolded and 

cured in water at 20±2
o
C for 28 days. For each mixture, twelve 

100mm cubes were made to determine the compressive 
strength and two 300×150mm diameter cylindrical specimens 
were used to determine the static modulus of elasticity. The 
flexure tensile strength was measured on 100×100×500mm 
prisms (Figure 1). The compressive strength was measured 
after 1, 3, 7, and 28 days (Figure 2). The flexural tensile 
strength, the stress-strain curve and the modulus of elasticity 
were determined at the age of 28 days. 

 

 
Fig. 1.  The concrete specimens. 

 
Fig. 2.  The cube compessive strength test. 

The studied types of concrete were: A control concrete 
stored in water at an ambient temperature (20

o
C) and concretes 

subjected to 8 different steam curing cycles (Table I). The 
curing cycles necessarily include four distinct phases: 

• Preheating period 

• Heating period 

• Maximum temperature period 

• Cooling period 

The molds were placed into the steam chamber, the latter 
being at the processing temperature. This steam chamber is 
equipped with a fan allowing the circulation of ambient air. A 
thermocouple was placed in the concrete in the middle of the 
central specimen of the cubic mold. After demolding, the 
concrete specimens were stored in water at 20

o
C 

TABLE I.  DIFFERENT TYPES OF CURING CYCLES 

Cycle 
Preheating 

period (h) 

Heating 

period (h) 

Max. Tem. 

period (h) 

Initial 

Tem. (
o
C) 

Max. 

Tem. (
o
C) 

Maturity 

(
o
C.h) 

A 0 2 3 20 70 350 

B 1.5 2 3 20 70 395 

C 3 2 3 20 70 440 

D 3 2 1.5 20 70 320 

E 3 2 0 20 70 200 

F 1.5 2 3 20 50 315 

G 1.5 2 3 24 70 405 

H 1.5 2.5 3 24 70 433 

 

III. RESULTS AND DISCUSSION 

A. Influence of the Duration of the Pre-Heating Period on 
Compressive Strength 

Figure 3 shows that the strength at the end of the treatment 
(0 days) and after 28 days of curing is minimal for zero 
preheating period. The decrease in final strength (28 days) 
compared to control concrete kept at 20

o
C is around 33%. For 

the cycles B and C, the fall is 26% and 15% respectively. So it 
is not advisable to heat the concrete immediately after pouring, 
which is in agreement with the results in [10]. The heating of 
fresh concrete causes the appearance of physical and chemical 
phenomena [17]. The physical order phenomena are essentially 
linked to the expansion of the various constituents of concrete 
under the effect of the rise in temperature. However, these 
various constituents have very different linear expansion 
coefficients. The rise in temperature causes the material to 
expand, which ultimately results in the appearance of pores. 
These pores indeed remain after the consolidation of the 
concrete structure. It is well known that the strength of concrete 
is inversely proportional to the number of pores in it. Chemical 
phenomena are linked to the appearance of insoluble, compact 
hydrate films, which oppose the subsequent penetration of 
water and somehow isolate the grains of cement [17]. 

 

 
Fig. 3.  The effect of the delay period on concrete strength. 



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B. Influence of the Speed of Temperature Rise on 

Compressive Strength 

In order to study the influence of the speed of temperature 
rising, the evolution of the compressive strength for heating at 
70

o
C with rise speeds of 18

o
C/h and 24.8

o
C/h are compared in 

Figure 4. It is observed that the best strength at 28 days is 
obtained for slowly heated concrete (18

o
C/h). However, the 

quality of treated concrete remains lower than that of control 
concrete. The drop in strength compared to control concrete is 
13% and 15% for concrete heated to 18

o
C/h and 24

o
C/h 

respectively. This confirms the results of [5]. The physical 
cause of this alteration is known: it is the very significant 
expansion of the constituents of fresh concrete, water and air. A 
high rate of temperature rise causes disorders in the structure of 
concrete which can go as far as the appearance of micro-cracks. 

 

 
Fig. 4.  The effect of heating period on concrete strength. 

C. Influence of Maximum Temperature 

When the temperature rises the compressive strength 
increases more rapidly at 0 days, whereas at 28 days, the 
strength of concrete treated at 50

o
C is greater than that of the 

concrete treated at 70
o
C (Figure 5). Authors in [7] found that 

the optimum maximum temperature of steam curing was near 
60ºC. However, higher temperatures of 70ºC and 80ºC show a 
distinct reduction in strength after 28 days [7]. A significant 
increase of compressive strength for fly ash mortars has been 
found at the early age of 3 days when curing temperature was 
raised [18]. 

D. Influence of the Maximum Temperature Period Time 

In order to study this phenomenon, three cycles of heat 
treatments (C, D and E) were considered, so the maximum 
temperature period varied from 0 to 3h. The three cycles had 
the same preheating period (3h), heating period (2h), and 
maximum temperature (70

o
C), however the maximum 

temperature period was 3, 1.5, and 0h respectively. It should be 
noted that the longer the maximum temperature period time, 
the higher the compressive strength in the short and long term 
is (Figure 6). Concrete maintained at a 3hour level presents, at 
28 days, a reduction in strength around 15% compared to 
control. For 1.5h and 0h concrete, the strength drop is around 
24% and 28%, respectively. Therefore, the greater the duration 
of the maximum temperature period, the smaller the drop in 

strength compared to control concrete at 28 days, which is in 
agreement with the results in [19]. 

 

 
Fig. 5.  The effect of maximum temperature on concrete strength. 

 
Fig. 6.  Effect of maximum temperature holding time on concrete strength. 

E. Maturity Factor 

We can see that the compressive strength after treatment 
increases with maturity (Figure 7). The latter is the sum of the 
product of temperature and time: 

( )10oMaturity T C t= + ×∆∑     (1) 

where T is the temperature in 
o
C and ∆t is the time interval (h). 

 

 
Fig. 7.  Relationship between maturity and cube compressive strength. 



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F. Tensile Strength 

The values of tensile strength are given in Table II. It can 
be seen that the maximum tensile strength (4.27MPa) is 
obtained by the control concrete. The tensile strength of all 
concrete mixtures was determined by the flexure test and is 
presented as a function of cube compressive strength in Figure 
8. The European Concrete Committee (CEB) suggests that the 
axial tensile strength (ft) can be related to the characteristic 
compressive strength (fc) by: 

2/3
0.3

t c
f f=     (2) 

The flexural tensile strength of all the concrete mixtures 
ranged between 2.9 and 4.27MPa. For a given compressive 
strength, the values for flexural tensile strength for all concretes 
are slightly higher than to the curve proposed by the CEB in 
(2). The ratio of the flexural tensile strength to the compressive 
strength was about 0.13. The results of [21] showed that the 
steam-curing provides better performance at 3 days for flexural 
strength and the ratio of the flexural tensile strength to the 
compressive strength was about 0.10. 

 

 
Fig. 8.  Relationship between tensile and cube compressive strength. 

TABLE II.  FLEXURAL TENSILE STRENGTH 

Cycle Control A B C D E F G H 

Tensile 

strength (MPa) 
4.27 3.45 3.75 3.64 3.72 3.86 4.01 2.90 4.14 

 

G. Stress-Strain Curve 

The stress-strain curves in compression of the control and 
both B and C concretes are shown in Figure 9. It is clear that 
the shape of the curves is similar for all concretes. Moreover, it 
is worth mentioning that before failure, it is difficult to assess 
any value for limiting axial strain. However, comparison can be 
made on the basis of 95% of failure stress. The limiting axial 
strain for control concrete is about 1880 microstrains. 
However, for concretes B and C, these values are 1420 and 
1596 microstrains respectively. These values are 24% and 15% 
lower than the control concrete's. The secant modulus of 
elasticity, as measured at a stress-strength ratio of 0.3 is shown 
in Table III. Compared with normal concrete, the values of 
concrete B and C are less by approximately 14% and 8% 
respectively. On the other hand, the value proposed by ACI 
[14] is 24.3GPa. This result is in agreement with the results in 
[20] for steam-cured slag concrete. 

 

 
Fig. 9.  Stress-strain curves for concretes in compression. 

TABLE III.  SECANT MODULUS OF ELASTICITY (GPA) 

Age (days) Control B C 

28 26.5 22.8 24.4 

 

IV. CONCLUSION 

For the materials and test conditions reported in this study, 
it was found that: 

• A decrease in the final strength of about 33% compared to 
that of the control concrete was observed for the cycle 
without pre-heating (Cycle A). However, for the cycles B 
and C (with pre-heating 1.5 and 3 hours), the decrease was 
26% and 15% respectively.  

• The greater the maximum temperature period time, the 
smaller the drop in compressive strength at 28 days 
compared to the control. 

• The best result for the treated concrete is obtained 
according to the following cycle: 

o A 3-hour of pre-heating period at 20
o
C,  

o A 2-hour increase of temperature from 20
o
C to 70

o
C, 

and  

o A 3-hour heating at the maximum temperature of 70
o 
C. 

ACKNOWLEDGMENT 

The current research was funded by the Deanship of 
Scientific Research at the University of Hail, Saudi Arabia, 
under the contract No. RG-191241. The authors would like to 
extend their gratitude to the Deanship of Scientific Research 
and to the College of Engineering at the University of Hail for 
providing all the required facilities. 

REFERENCES 

[1] A. A. Jhatial, S. Sohu, N. ul K. Bhatti, M. T. Lakhiar, and R. Oad, 
"Effect of steel fibres on the compressive and flexural strength of 

concrete," International Journal of Advanced and Applied Sciences, vol. 
5, no. 10, pp. 16–21, Oct. 2018, https://doi.org/10.21833/ijaas.2018. 

10.003. 



Engineering, Technology & Applied Science Research Vol. 11, No. 2, 2021, 6974-6978 6978 
 

www.etasr.com Boukendakdji et al.: The Effects of Steam-Curing on the Properties of Concrete 

 

[2] R. Nayaka, G. S. Diwakar, and V. Gudur, "Effect of Steam Curing on 
the Properties of High Early Strength Silica Fume Concrete," IOP 

Conference Series: Materials Science and Engineering, vol. 431, no. 4, 
Nov. 2018, Art. no. 042011, https://doi.org/10.1088/1757-899X/431/4/ 

042011. 

[3] J. L. García Calvo, M. C. Alonso, L. Fernández Luco, and M. Robles 
Velasco, "Durability performance of sustainable self compacting 

concretes in precast products due to heat curing," Construction and 
Building Materials, vol. 111, pp. 379–385, May 2016, https://doi.org/ 

10.1016/j.conbuildmat.2016.02.097. 

[4] A. M. Ramezanianpour, Kh. Esmaeili, S. A. Ghahari, and A. A. 
Ramezanianpour, "Influence of initial steam curing and different types 

of mineral additives on mechanical and durability properties of self-
compacting concrete," Construction and Building Materials, vol. 73, pp. 

187–194, Dec. 2014, https://doi.org/10.1016/j.conbuildmat.2014.09.072. 

[5] M. Boukendakdji, J. J. Brooks, and P. J. Wainwright, "Influences of 

steam curing on strength, shrinkage and creep of OPC and slag 
concretes," in Radical concrete technology: proceedings of the 

international conference held at the University of Dundee, Dundee, 
Scotland, UK, Jun. 1996, https://doi.org/10.1201/9781482294941-49. 

[6] K. Elakkiya, N. Una, and A. Govandan, "Effect of thermal and 

microwave oven curing on concrete," Indian Journal of Scientific 
Research, vol. 17, no. 2, pp. 262–267, 2018. 

[7] S. Türkel and V. Alabas, "The effect of excessive steam curing on 

Portland composite cement concrete," Cement and Concrete Research, 
vol. 35, no. 2, pp. 405–411, Feb. 2005, https://doi.org/10.1016/ 

j.cemconres.2004.07.038. 

[8] J.-S. Park, Y. J. Kim, J.-R. Cho, and S.-J. Jeon, "Early-Age Strength of 
Ultra-High Performance Concrete in Various Curing Conditions," 

Materials (Basel, Switzerland), vol. 8, no. 8, pp. 5537–5553, Aug. 2015, 
https://doi.org/10.3390/ma8085261. 

[9] M. A. Panhyar, S. N. R. Shah, F. A. Shaikh, and A. A. Jhatial, 

"Influence Of Casting Temperature On The Structural Behavior Of 
Concrete," Engineering, Technology & Applied Science Research, vol. 

9, no. 4, pp. 4480–4483, Aug. 2019, https://doi.org/10.48084/etasr.2924. 

[10] B. Liu, Y. Xie, and J. Li, "Influence of steam curing on the compressive 
strength of concrete containing supplementary cementing materials," 

Cement and Concrete Research, vol. 35, no. 5, pp. 994–998, May 2005, 
https://doi.org/10.1016/j.cemconres.2004.05.044. 

[11] Y.-J. Kim, S.-W. Kim, C.-W. Park, and J.-S. Sim, "Compressive 
Strength Properties of Concrete Using High Early Strength Cement and 

Recycled Aggregate with Steam Curing Conditions," Journal of the 
Korean Recycled Construction Resources Institute, vol. 4, no. 1, pp. 76–

81, 2016, https://doi.org/10.14190/JRCR.2016.4.1.076. 

[12] A. Makani, T. Vidal, G. Pons, and G. Escadeillas, "Time-dependent 
behaviour of high performance concrete: influence of coarse aggregate 

characteristics," EPJ Web of Conferences, vol. 6, p. 03002, 2010, 
https://doi.org/10.1051/epjconf/20100603002. 

[13] A. H. Buller, M. Oad, and B. A. Memon, "Flexural Strength of 

Reinforced Concrete RAC Beams Exposed to 6-hour Fire – Part 2: Rich 
Mix," Engineering, Technology & Applied Science Research, vol. 9, no. 

1, pp. 3814–3817, Feb. 2019, https://doi.org/10.48084/etasr.2494. 

[14] A. Hanif, Y. Kim, K. Lee, C. Park, and J. Sim, "Influence of cement and 
aggregate type on steam-cured concrete – an experimental study," 

Magazine of Concrete Research, vol. 69, no. 13, pp. 694–702, Apr. 
2017, https://doi.org/10.1680/jmacr.17.00015. 

[15] S.-D. Hwang, R. Khatib, H. K. Lee, S.-H. Lee, and K. H. Khayat, 

"Optimization of steam-curing regime for high-strength, self-
consolidating concrete for precast, prestressed concrete applications," 

PCI Journal, vol. 57, no. 3, pp. 48–62, Jun. 2012, https://doi.org/ 
10.15554/pcij.06012012.48.62. 

[16] 318-08: Building Code Requirements for Structural Concrete and 

Commentary. Farmington Hills, MI, USA: American Concrete Institute, 
2008. 

[17] A. M. Neville, Properties of Concrete, 5th ed. Harlow, England, UK ; 
New York, NY, USA: Trans-Atlantic Publications, 2012. 

[18] J. Payá, J. Monzó, M. V. Borrachero, E. Peris-Mora, and F. Amahjour, 

"Mechanical treatment of fly ashes: Part IV. Strength development of 

ground fly ash-cement mortars cured at different temperatures," Cement 
and Concrete Research, vol. 30, no. 4, pp. 543–551, Apr. 2000, 

https://doi.org/10.1016/S0008-8846(00)00218-0. 

[19] M. Ba, C. Qian, X. Guo, and X. Han, "Effects of steam curing on 
strength and porous structure of concrete with low water/binder ratio," 

Construction and Building Materials, vol. 25, no. 1, pp. 123–128, Jan. 
2011, https://doi.org/10.1016/j.conbuildmat.2010.06.049. 

[20] M. Boukendakdji, "Mechanical properties and long-term deformation of 

slag cement concrete," Ph.D. dissertation, University of Leeds, Leeds, 
UK, 1989. 

[21] Y. H. Ahmed and R. Azhari, "Effect of atmospheric steam curing 
parameters on concrete strength and durability," in Second Conference of 

Civil Engineering in Sudan, Khartoum, Sudan, Dec. 2018, pp. 48–54.