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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 66, 2018 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Songying Zhao, Yougang Sun, Ye Zhou
Copyright © 2018, AIDIC Servizi S.r.l. 
ISBN 978-88-95608-63-1; ISSN 2283-9216 

Study on Hydration Heat Coefficient of Mass Concrete 
Construction 

Hongli Wang 
School of Architectural Engineering, Shaanxi Vocational and Technical College, Xi'an 710038, China 
hongliwang56374@163.com 

This paper aims to prevent and control the hydration heat crack by analyzing the hydration heat coefficient in a 
bridge construction project, in which process it explores the reasons and concrete parameters as well as takes 
corresponding control measures. The analysis suggests that the reason for the hydration heat phenomenon in 
this project lies in temperature change. And the conclusion is that the calculation precision of the analysis 
fitted by cubic polynomials is higher than that of traditional analysis fitted by quadratic polynomials, so that the 
hydration heat phenomenon can be dealt with in a better way. 

1. Introduction 
At the initial stage of the hardening of concrete, the water spray effect between cement and waterborne raw 
materials releases relatively a large amount of heat that increases the overall temperature of the concrete, 
which is called hydration heat phenomenon and is common in many kinds of concrete structures. In normal 
size concrete structures, due to the high heat dissipation condition, the internal and external temperature 
difference of concrete in hydration heat process doesn’t change too much and serious engineering cracks 
rarely occur. However, in the mass concrete structures in modern construction projects, its heat dissipation 
condition is limited due to its large mass so that the heat cannot be dissipated rapidly and the internal and 
external temperature difference of concrete tends to be a big one, which may lead to the creation of harmful 
cracks. 
Since the scale of modern concrete construction projects is on the rise, the hydration heat phenomenon has to 
be controlled. Therefore, this paper based on previous studies, analyzes a large bulk road and bridge 
construction project in the aspects of temperature field, temperature stress, and coefficient of hydration heat of 
concrete, and provides corresponding suggestions on hydration heat temperature control and crack 
prevention. 

2. Literature review 
The research on temperature field and temperature stress of mass concrete structure started at the building of 
the Hoover dam with high 221m in the United States in the mid-1930s. At that time, the United States Bureau 
of reclamation organized the new construction technology research, such as water pipe cooling, low 
temperature air cooling and assembly precast blocks, and achieved satisfactory results. Many of the mass 
concrete technologies adopted by Hoover dam are still in use. 
Since 1940s, many countries, such as the United States Bureau of reclamation, the former Soviet Institute of 
water engineering and the scholar Alzyoud, have made a thorough study of the actual design, construction 
technology, temperature control index and temperature control measures of the mass concrete structure, such 
as the laminated block of the pouring block. The proper reduction of cement content, Low thermal cement, 
various aggregate precooling methods, and calculation of temperature field and temperature stress are 
selected. The emphasis is on the prevention of cracks in the mass concrete structure, and various technical 
measures for effective treatment of the existing cracks are also explored (Alzyoud et al., 2016). 
The Fifteenth International dam conference held in 1985 listed concrete cracks as one of the four topics of the 
conference. In 1992 at the third RCC conference in Santiago, California, Batog and Giergiczny creatively 
introduced the classic concrete dispersion crack model into the analysis of dam thermal stress (Batog and 

                                

 
 

 

 
   

                                                 
DOI: 10.3303/CET1866198 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Wang H., 2018, Study on hydration heat coefficient of mass concrete construction, Chemical Engineering 
Transactions, 66, 1183-1188  DOI:10.3303/CET1866198   

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Giergiczny, 2017), the scholars Frenzel and Curbach first calculate the temperature field of the dam by the 
finite element method and the difference method, and use the ADINA program to calculate the three-
dimensional stress field, and predict the possibility of the cracking of the palace otter dam during the 
construction period and the operation period (Frenzel and Curbach, 2017). 
After 1950s, a lot of work has been done on the research of the temperature field and the temperature stress 
of the mass concrete structure, and great achievements have been made. In early 50s, two arch dams of Fuzi 
ridge and Meishan were built in the middle reaches of Huaihe. The longitudinal slot of the Fuzi ridge dam is 
set up in the piers, and then backfilled with concrete. There are basically no cracks in the piers, but there are 
more cracks in the arch. In the design of Meishan multi arch dam, there are contraction joints in the arch, and 
there are not many cracks after completion. China has attached great importance to the numerical analysis 
and theoretical study of the temperature stress of the mass concrete structure. In 1973, the academician Zhu 
Bofang of China Institute of water conservancy and Hydroelectric Science and technology developed the first 
finite element program of the temperature creep stress of the concrete in China and applied it to the analysis 
of the temperature stress in the bottom hole of Sanmenxia. At the end of 70s, Tongji University, Hohai 
University and Tsinghua University carried out corresponding research and application. 
Scholar Ghasemzadeh and others completed the 2D and 3D finite element simulation program system of the 
large concrete structure from 1990 to 1992 combined with the Xiaolangdi Dam project (Ghasemzadeh et al., 
2016). Scholars Haar and Marx use the artificial short joints to solve the problem of temperature tensile stress 
on both sides of the RCC arch dam, and the simulation of pipe cooling is easy to handle. They also consider 
the environmental factors and the randomness of the thermodynamic parameters of concrete, and give the 
random variational principle and the random finite element formula which can reflect the randomness of the 
material parameters (Haar and Marx, 2017). 
Since the end of the last century, many colleges and universities have carried out the research on the 
temperature stress of mass concrete structures. The calculation of the temperature stress of large volume 
concrete, such as Longtan, Xiaowan, Xiluodu and TGP, has been carried out and valuable results have been 
obtained. 
In 1950s, the economic and technical level of our country was low, and the large volume concrete was only in 
a few key projects such as large dams, and it was rarely encountered in small and medium sized projects. 
However, from the late 70s, especially in the 90s, large industrial buildings, public buildings, high rise high-rise 
civil buildings flourished, and more and more large volume reinforced concrete engineering. In recent years, 
domestic and foreign scholars have done a lot of experimental, theoretical and numerical analysis on the 
temperature problem. The research on temperature field and temperature stress of mass concrete structure in 
China is more comprehensive and thorough and has reached a higher level. The calculation of the 
temperature field and the temperature stress is developed from the two-dimensional finite element model to 
the three-dimensional finite element model, and the technical level of the numerical analysis method has been 
greatly improved. 
In the field of civil engineering, Professor Wang Tiemeng of China Metallurgical Building Research Institute 
has been devoted to the study of cracks in civil engineering structures. Professor Wang Tiemeng has been 
engaged in the research of mass concrete in 50s. For many years, Klemczak and others have carried out field 
scientific experiments and theoretical research in combination with engineering practice and have solved a 
great number of technical problems for national key construction (Klemczak et al, 2017). Scholar Saeed and 
others put forward the basic formula for the concrete structure to bear the continuous restrained temperature 
shrinkage stress, and accordingly formed a set of comprehensive control theory and approximate calculation 
method of “anti” and “put”. By using the comprehensive research method, the design principles of “anti” and 
“put” are put forward, and the technical viewpoints of two design schools with slit and no slit are unified, and 
the calculation formulas of expansion joint and crack control are put forward in combination with practice 
(Saeed et al., 2015). Zhu and other scholars have developed a set of three-dimensional finite element 
temperature analysis program package 3D-TEEP, which can simulate the actual construction process of 
concrete, considering complex factors such as the concrete layered casting, pouring layer thickness, pouring 
temperature, construction intermittence, concrete hydration heat divergence law, maintenance mode, external 
temperature change, concrete and foundation elasticity, modulus change and creep (Zhu et al., 2016). 
To sum up, the above research work mainly studies the theoretical research on the temperature cracks in the 
mass concrete structure to improve the crack resistance design theory of large volume concrete. Starting from 
the actual problem of mass concrete, the internal temperature of concrete increases rapidly because of the 
concrete hydration and exothermic during the early hydration process. For large volume concrete, the 
appearance of temperature difference in the inner surface is accompanied by the emergence of the 
temperature stress, and the early temperature stress is very considerable, so the concrete surface is pulled. If 
the tensile stress exceeds the tensile stress of the surface concrete, it will have a negative effect on the 
stability of the structure. Therefore, based on the above research status, this paper makes a comprehensive 

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analysis of the temperature stress related problems of the civil structure based on the study of the temperature 
field and the temperature stress of the predecessors. 

3. Research method 
3.1 Layout of monitoring scheme of hydration heat temperature sensor 

In order to analyze the temperature field and stress of the specific bridge construction project, a temperature 
sensor is installed for detection in the construction site. In the installing process: the size of the 15# pier 
bearing platform is 19.2m×13m×4m; the strength degree of the concrete is C40; the amount of different kinds 
of materials in per cubic meter concrete is: 291kg P.42.6 (low alkali) cement, 750kg sand, 1080kg granite, 
125kg admixture (fly ash), 4.16kg water reducing agent, and 154kg water; during the construction, pour 
concrete into the steel framework, and prearrange two layers of cooling water pipes which is made of DN50 (2 
inch) galvanized steel; the horizontal and the vertical spacing of cooling water pipes is 2 m respectively, and 
the overall circulating water supply (only one inlet and outlet) is adopted. The installation of the temperature 
monitoring point area mainly aims to reflect the internal and external temperature difference, cooling speed 
and environmental temperature of mass concrete blocks. As the 15# pier bearing platform has a symmetrical 
structure, the number of sensors can be reduced, and only a few representative points are needed. There are 
six temperature monitoring points installed, and the position of the sensor is shown in Figure 1, in which 
measuring point 1 is located at 1m above the center of the bottom surface of the bearing platform; point 2 is 
located at the center of the dark side of the bearing platform; point 3 is at the center of the bearing body; point 
4 and 5 are located at the up and down 1/4 points of the diagonal of the bearing body respectively; point 6 is 
located near the cooling water pipes.  

 

Figure 1: The schematic layout of the sensor (cm) 

The temperature sensor adopted by the temperature monitoring is AD592 integrated temperature sensor, 
which has high measurement accuracy and its measurement range is -25~105� (the error is less than + / - 
0.1 �); Each sensor has a unique ID number to facilitate data collection and recording. The temperature 
readout adopts LTM8261 handheld multipoint temperature tester, which can provide power for battery, and 
test and code the sensor without computer, indicating that it’s suitable for the application in occasions without 
computer, as shown in Figure 2. To ensure that the temperature sensor is not damaged during concrete 
pouring, it is installed on the lower edge of the steel bar or angle steel and an insulating tape is placed 
between the temperature sensor and the steel bar. In order to facilitate the temperature monitoring work, the 
leads of the temperature sensor are stretched out the bearing platform uniformly, and data collection is carried 
out at appropriate positions. During 329 h after concrete pouring of 15# pier bearing platform, this paper 
measures the temperature of each measuring point, and the data has been recorded. Due to severe change 
of the hydration heat temperature in the initial stage of concrete pouring, the initial interval for data collection is 
2 h, and it is adjusted as 4 h after the change tends to be slow, finally it is adjusted as 10 h the temperature 
becomes stable. 

 

Figure 2: The temperature sensor and handheld temperature readout 

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3.2 Field measurement and data analysis 

Concrete pouring of 15# pier bearing platform began at 11 a.m. on August 18, 2011, and the molding 
temperature is 32.3 �. When the concrete was poured to 3.2 meters from the bottom of the bearing platform, 
the cooling water pipe began to enter the water. The pouring was completed at 8 a.m. on August 20, and the 
cooling pipes stopped water supply at 11 a.m. the next day. The concrete steel formwork on the bearing 
platform was removed at 2 p.m. on August, 22. According to the temperature monitoring scheme, the 
monitoring data of hydration heat temperature of 15# pier bearing platform were collected and recorded, but it 
is not elaborated here due to the limitation of space. 
First of all, in order to facilitate the analysis of hydration heat temperature changes at each measuring point, 
the temperature data of all measuring points measured and collected in the field during 329 h after the 
concrete pouring of 15# pier bearing platform were plotted into a temperature curve. Measuring point 1 is 
located 1m above the center of the bottom of the bearing platform. Starting counting when the concrete is 
poured at point 1, the temperature curve is shown in Figure3.  

 

Figure 3: The hydration heat temperature curve of measuring point 1 

From Figure 3, it can be seen that within 16 h, the temperature of the concrete at measuring point 1 rose 
sharply, reaching 80% of the highest temperature; and then the temperature rise trend slowed down. In the 61 
h after molding, the temperature of the concrete at measuring point reached 68.9 �, the highest temperature, 
and the temperature lasted until 90 h. Then it began to slow down and tended to be stable. In the 318 h after 
molding, the concrete temperature of point 1 dropped to 54.2 �, compared with the highest temperature, 
decreased by 21%. Therefore, the maximum temperature rise of concrete at point 1 was 38.5 �, and the 
average cooling rate was 1.37 � / d, which met the requirements of the 3.0.4 term in Mass Concrete  
Construction Specifications (GB50496--2009): the cooling rate of concrete pouring body should not be greater 
than 2.0 � / d. 
Secondly, the temperature curve of hydration heat at measuring point 2 was analyzed. Measuring point 2 is 
located at the center of the dark side of the bearing platform. Starting counting when the concrete is poured at 
point 2, the temperature curve is shown in Figure 4. 

 

Figure 4: The hydration heat temperature curve of measuring point 2 

According to the figure, it can be seen that in the 10 h after molding, the temperature of the concrete reached 
the highest 51.6�, and then it began to decrease. In the 306 h, the temperature dropped to 31.5�, which is 
consistent with the temperature of the surrounding atmosphere. The maximum temperature rise of concrete at 
point 2 was 19.9�, and the average cooling rate was 1.63 � / d, which met the requirements of the regulation. 
Since measuring point 2 is located at the center of the dark side of the bearing platform, which was influenced 
greatly by the external environment, so that the temperature at this point fluctuated with the ambient 
temperature, but the overall temperature changing tendency was dropping after reaching the highest 
temperature, and the final temperature change tends to be moderate. Under the influence of night cooling and 

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air convection, the temperature at measuring point 2 was significantly lower than that at other measuring 
points. 

3.3 Numerical simulation analysis 

When the value of thermal performance parameters of concrete has not been obtained, it can be estimated 
according to the weight percentage of each component of concrete. According to the mix proportion of 
concrete of 15# pier bearing platform, the amount of each component of per cubic meter C40 adopted is as 
follows: 291 kg cement, 750 kg sand, 1080 kg granite, and 154 kg water. Table 1 shows the heat conductivity 
coefficient and the specific heat of each component. 

Table 1: The heat conductivity coefficient and specific heat of main component 

Constituent components Thermal conductivity specific heat 
water 2.160 4.187 
Ordinary cement 4.593 0.536 
Quartz sand 11.099 0.745 
Granite 10.467 0.708 

4. Results and discussion 
4.1 Modeling 

The entity units in finite element analysis software MIDAS/Civil 2010 are adopted for modeling, which can be 
used for thermal analysis of 3d steady state or transient state. The model has 17431 nodes and 14848 entity 
units. According to the actual layout of cooling water pipes in the construction site, there are 2 layers of 
cooling water pipes in the calculation model of 15# pier bearing platform, the horizontal and vertical spacing of 
which is 2 m. The concrete hydration heat temperature in the 320 h after modeling at each measuring point 
can be calculated. In order to facilitate the analysis, the concrete hydration heat temperatures calculated at 
each measuring point are plotted into a temperature curve, as shown in Figure 5. 

 

Figure 5: The calculated hydration heat temperature curve of each measuring point 

The calculated results show that the variation trend of hydration heat temperature at each measuring point is 
basically the same: the initial temperature rise rate is relatively fast, and the maximum temperature is reached 
around 50h after the concrete is poured into the mold, and then the temperature begins to decrease. As can 
be seen from Figure 5, influenced by cooling water, the rise speed of concrete temperature slows down, and 
the temperature of concrete near the cooling water pipe drops sharply. After the cooling system is closed, the 
dropping trend of concrete temperature at each measuring point of the bearing platform slows down. 
Influenced by environment temperature and air convection, the temperature decline of measuring points on 
surface is relatively obvious, which is 15 � lower than that of other measuring points at the same time. 

4.2 Contrastive analysis of measured data and calculated results 

In order to verify whether calculated temperature is consistent with the measured temperature on site, the 
calculated values at each measuring point are compared with the measured ones. In addition to the values at 
point 2, other measured values are roughly consistent with the calculated temperature curve, among which the 
temperature curve calculated by MIDAS/Civil 2010 is smoother than the measured one since many influencing 
factors in actual situation are ignored in the finite element analysis. The calculated values at point 1 are in 
good agreement with the values obtained from the actual measurement: the calculated temperature curve 
reaches the maximum temperature at 63h, and the measured temperature curve reaches the at 72h. The 
actual measured temperature at point 2 is entirely 10 ℃ lower than the corresponding calculated temperature; 

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Although the general trend of the two values is downward, the falling trend of the measured curve is more 
similar to the change of atmospheric temperature. This shows that in the actual situation, the surrounding 
environment has a great influence on the hydration heat temperature of concrete. 

5. Conclusion 
In this study, it is found that the temperatures of the measuring points on the same section of 15# pier bearing 
body in the example project are distributed in a symmetric parabola along the pier wall thickness, therefore the 
method fitted by quadratic polynomial is adopted and the calculation formula of temperature distribution is 
achieved. Comparing the calculated and measured values by quadratic polynomial, it is found that the 
maximum calculation error is 13%, which is reasonable. Finally the measured temperature values along the 
thickness of 15# pier bearing body are fitted by cubic polynomial, during which process the maximum 
calculation error is 6.6%, an obvious higher accuracy than the results of formula fitted by quadratic polynomial. 
The results show that at measuring point 1, the calculated curve is in good agreement with the measured one, 
and the calculated curve reaches the maximum temperature at 63h. The actual measured temperature at 
point 2 is entirely 10 � lower than the corresponding calculated temperature; Although the general trend of the 
two values is downward, the falling trend of the measured curve is more similar to the change of atmospheric 
temperature. 

Reference  

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Batog M., Giergiczny Z., 2017, Influence of mass concrete constituents on its properties, Construction & 
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Frenzel M., Curbach M., 2017, Shear strength of concrete interfaces with infra‐lightweight and foam concrete, 
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Ghasemzadeh F., Rashetnia R., Smyl D., 2016, A comparison of methods to evaluate mass transport in 
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Klemczak B., Batog M., Pilch M., 2017, Analysis of Cracking Risk in Early Age Mass Concrete with Different 
Aggregate Types, Procedia Engineering, 193, 234-241, DOI: 10.1016/j.jmr.2017.08.006 

Saeed M., Rahman M., Baluch M H., 2015, Early age thermal cracking of mass concrete blocks with Portland 
cement and ground granulated blast-furnace slag, Magazine of Concrete Research, 68(13), 1-17, DOI: 
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Zhu W., Chen Y., Li F., 2016, Design and preparation of high elastic modulus self-compacting concrete for 
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