Effect of Thermal Parameters on Hydration Heat Temperature and Thermal Stress of Mass Concrete

To explore the influence of concrete thermal parameters on the hydration heat temperature and thermal stress of mass concrete, four feature positions of a dam foundation were chosen to analyze the changing process of temperature and stress by varying the thermal parameters, including the thermal conductivity, specific heat, surface heat diffusion coefficient, temperature rise coefficient, solar absorption coefficient, and thermal expansion coefficient. Some conclusions were obtained as follows. Increasing the thermal conductivity and reducing the specific heat and temperature rise coefficient of concrete can effectively reduce the maximum temperature of the central concrete structure. Increasing the solar absorption coefficient, specific heat, and thermal expansion coefficient and reducing the thermal conductivity, surface heat diffusion coefficient, and temperature rise coefficient of concrete can reduce the maximum principal tensile stress in the structure to a certain extent.,emaximum principal tensile stress at different positions of the structure has a linear functional relationship with the thermal conductivity, specific heat, and thermal expansion coefficient and has a quadratic function relationship with the surface heat diffusion coefficient, temperature rise coefficient, and solar absorption coefficient. Besides, this study also proposed a series of related anticracking measures. ,is study was expected to provide a theoretical reference for the design, construction, and cracking disease prevention of mass concrete structures.


Introduction
e large hydration heat can be produced in a short time during the casting of mass concrete structure, which leads to the rapid rise of the internal temperature of the mass concrete structure. Especially, the mass concrete structure is also affected by the external environment and the thermal parameters, which is easy to form a large thermal gradient and thermal stress between the core and the surface. As a result, cracks will occur when the thermal stress is larger than the tensile strength of the concrete. erefore, temperature control is particularly important to the mass concrete [1]. To ensure the integrity and durability of mass concrete structure, the hydration heat temperature, thermal stress distribution, and influencing factors of mass concrete structure in the cold region are analyzed, and taken appropriate temperature control measures are the keys to construction organization design and comprehensive treatment of mass concrete structure diseases.
At present, some researchers have carried out lots of studies to analyze the temperature field, thermal stress, and influencing factors of mass concrete by using the finite element method and monitoring method. Some studies [2][3][4][5][6][7][8][9] found that the results of numerical calculation can accurately predict the distribution of temperature and stress of the structure by comparing with the field monitoring data, and it is feasible to put forward effective temperature control measures for the mass concrete structure according to the finite element simulation results by considering various influencing factors comprehensively at the design stage. So far, the influencing factors such as construction measures, amount and type of concrete material, and pipe cooling parameters have been studied. Reducing concrete casting temperature [10][11][12][13][14], changing casting date [15,16], layered casting [17][18][19], and curing concrete [20,21] can effectively reduce the maximum temperature of the structure. At the same time, changing insulation thickness [22] and types of insulation materials [23] has significant effects on the temperature difference and maximum tensile stress of the structure. e amount and type of concrete raw materials have a significant influence on the internal heat transfer and mechanical properties of concrete. High cement content [24][25][26] will make the temperature of the structure exceed the specified limit. Low temperature cement [27][28][29] can reduce the structure temperature and improve the crack resistance of the concrete structure. Additives [30][31][32][33][34] can also effectively reduce the temperature rise of cement hydration heat. e arrangement of cold water pipes is a very effective method to reduce the heat of hydration [35]. Controlling the inlet and outlet temperature of cooling water pipes, the spacing of cooling pipes, and adjusting the convection coefficient [36] between cooling water and concrete are effective measures to control the hydration heat of concrete. Meanwhile, medium-term temperature control and cooling [37] are also very important. Besides, Si et al. [38] also put forward a new idea that the small temperature difference cooling can effectively reduce the temperature gradient and thermal stress. In conclusion, these findings mainly focused on revealing the influence of construction design, amount and type of concrete raw materials, pipe cooling parameters on the hydration temperature, and thermal stress distribution of mass concrete. However, the thermal parameters are also closely related to the thermalmechanical characteristics of mass concrete structure, such as the thermal conductivity is a factor that directly affects the temperature gradient of the structure. erefore, it is extremely important to study the influence of concrete thermal parameters on temperature and thermal stress distribution of mass concrete structure for crack control and disease treatment, especially for the mass concrete structure located in the cold region where the temperature changes greatly.
is study relied on Xiwugaigou Roller Compacted Concrete Dam Project in Inner Mongolia, China. A threedimensional finite element model considering hydration heat release, thermal parameters changing, and actual temperature boundary was built to analyze the maximum temperature, the temperature difference between the core and surface, and maximum principal tensile stress of the mass concrete aiming to study the influence of different values of thermal conductivity, specific heat, surface heat diffusion coefficient, temperature rise coefficient, solar absorption coefficient, and thermal expansion coefficient on the distribution of temperature and thermal stress at the core, surface, 50 mm from the surface, and foot of the concrete foundation. Furthermore, the functional relationship between different thermal parameters and the maximum principal tensile stress at different positions of the structure is determined. Finally, the study also puts forward a series of relevant crack prevention measures. e results will provide a theoretical basis for temperature control and crack prevention of mass concrete structures from the perspective of controlling the thermal properties of concrete materials.

Heat Conduction Equation.
For isotropic solids, the heat conduction equation considering concrete hydration heat is expressed as follows: where T is the temperature of the concrete, τ is the time, λ is the thermal conductivity, c is the specific heat, ρ is the density of concrete, and θ(τ) is the adiabatic temperature rise induced by hydration heat, which is calculated as follows: where θ 0 is the adiabatic temperature rise terminal value, and m is the temperature rise coefficient.

Implicit Expression of Unsteady Temperature Field.
Equation (1) becomes a matrix differential equation about the time after spatial discretization by the finite element method. e matrix differential equation is given as follows: where [K] is the heat conduction matrix, [C] is the heat capacity matrix, and R { } is the thermal load vector. Assume τ � τ i corresponds to T � T i and τ � τ i+1 corresponds to T � T i+1 ; then, ΔT i can be defined as Substituting equation (5) in equation (4) obtains So equation (4) becomes 2 Advances in Materials Science and Engineering e temperature of each node at any time can be obtained by solving the equations. e parameter b is usually taken as 1 in the calculation, which is the backward differential method.

Finite Element Method for Elastic Creep ermal Stress of
Concrete. Assume that concrete is an elasticity-creep solid. e thermal stress of concrete is calculated by the finite element method without considering the drying shrinkage of concrete [39]. In a three-dimensional space, the strain increment generated in Δτ n � τ n − τ n−1 can be expressed as follows: Δε n � ε τ n − ε τ n−1 � Δε e n + Δε c n + Δε T n , (9) where Δε n is the strain increment, Δε e n is the elastic strain increment induced by the external force, Δε c n is the creep strain increment, and Δε T n is the temperature strain increment. e elastic strain increment is calculated as follows: where τ n is the median age of the concrete, equals to ((τ n + τ n−1 )/2), E(τ n ) is the modulus of elasticity of the concrete at median age, [Q] is a coefficient matrix, and Δσ n is the stress increment. e creep strain increment is calculated as follows: where η n is a matrix related to the creep coefficient, and C(t n , τ n ) is the specific creep of the concrete at median age. en, the relationship between stress increment and strain increment is given as follows: where [D n ] is the stress-strain matrix corresponding to E(τ n ). e unit node force increment can be expressed as follows: where ΔF { } e is the element nodal force increment, and [B] T is the transformation matrix of the deformation matrix [B]. e above formula can be written as follows: where [k] e is the element stiffness matrix. Define where ΔP n c e is the element node load increment by creep, and ΔP n T e is the element node load increment by temperature. erefore, the global balance equation is given as follows: where [K] is the global stiffness matrix, ΔP n L is the nodal load increment by external loads, ΔP n C is the node load increment by creep, and ΔP n T is the node load increment by temperature.
Finally, the stresses of each unit are as follows:

Methods
e Xiwugaigou Reservoir Project, located in Inner Mongolia which is the typical cold region, consists of gravity dam, flood discharge, sand scouring tunnel, and diversion tunnel. According to the difference of materials, it can be divided into foundation section, water retaining section, overflow dam section, flood discharge, sand scouring tunnel section, diversion tunnel section, and joint parts. e maximum dam height is 43.4 m, dam length is 224.0 m, dam crest width is 5.0 m, and the height of the foundation section located in the strong restraining from the area of the dam is 1-3 m. To study the influence of concrete thermal parameters on hydration heat temperature and thermal stress of mass concrete, a three-dimensional finite element model of the dam foundation is established.

Finite Element Model.
e highest foundation dam section with the size of 30 m (length) * 20 m (width) * 3 m (height) is chosen as the study object, which is located on the bedrock foundation, with the size of 40 m (length) * 30 m (width) * 5 m (height). As shown in Figure 1, four feature research points are setup to analyze the changing process of temperature and stress by varying the thermal parameters. Point A is located in the core of the structure, where the maximum temperature occurs. Point B is located 50 mm away from the surface near the boundary area, which is the keypoint to calculate the temperature difference between the core and surface. Point C is located at the surface through which the surface temperature distribution of the structure can be observed directly. And point D is on the foot of the concrete structure which is one of the most prone stress concentration points. e boundary of the concrete foundation and bedrock is divided into 50 mm grids, and others are divided into 1.0 m grids in the model. e finite element model is shown in Figure 2.

Initial and Boundary Conditions.
e initial placing temperature of concrete is taken as the initial temperature of concrete and foundation using the following calculation: where T 0 is the initial casting temperature of the concrete taken as 20°C in considering the actual project and construction experience.

Advances in Materials Science and Engineering
In the calculation of the stress field, the boundary of the bedrock bottom is set as the fixed displacement constraint, the sides set as the normal displacement constraint, and the other sides of the model are the free surfaces. In the calculation of temperature field, the bottom and side of bedrock are set as the adiabatic boundaries, and the contact surface between bedrock and air and the surface between concrete and air are all set as the third boundary conditions, as shown in the following equation: where β is the surface heat diffusion coefficient. T a is the environment temperature, which is obtained by the monitoring data of the study area, and can be expressed by the following periodic function: where t is the time (day), t � 0 corresponds to May 1 st , t � 1 corresponds to May 2 nd , and so on. To intuitively see the temperature change of the project site, we present equation (20) in Figure 3. e curve shows that the project site is located in the cold region for negative temperature that occurs in the winter. e red part of the curve is the boundary temperature used in the modeling.

Parameters Data.
e concrete is C20 normal concrete with the density of 2360 kg/m 3 , the elastic modulus of 25.5 GPa, and Poisson's ratio of 0.167. e adiabatic temperature rise of concrete is calculated by equation (2), and the final value of temperature rise is 30°C. e parameters of bedrock are shown in Table 1.
e main parameters influencing the thermal performance of concrete are thermal conductivity, specific heat, temperature rise coefficient, surface heat diffusion coefficient, solar absorption coefficient, and thermal expansion coefficient [40,41]. ese parameters are the basic data for solving the thermal stress caused by the temperature change inside the concrete structure, which mainly depends on the concrete age, aggregate type, cement type, water-cement ratio, unit weight, and temperature. erefore, thermal parameters are explored as variables in this study. e values of each thermal parameter are shown in Table 2, which cover the possible range in the construction [41,42].

Temperature Control Requirements.
When the thermal stress exceeds the bearing limit of concrete, the structure will be broken, resulting in thermal cracks. According to the Chinese standard for construction of mass concrete [43], the maximum temperature of the foundation should not exceed 70°C, the temperature difference between the core and surface should not exceed 25°C, and the allowable principal tensile stress of the concrete is 2.45 MPa at the age of 28 days of concrete.

Results and Discussion
Based on the concrete foundation model, the influence of each thermal parameter on the maximum temperature, the temperature difference between the core and surface, and maximum principal tensile stress of mass concrete are analyzed by using the control variate method. Figure 4 shows the relationship of temperature over time with four different thermal conductivities, which are 0.5 W/(m·K), 1.5 W/ (m·K), 2.5 W/(m·K), and 3.5 W/(m·K), respectively. As shown in Figure 4, the temperature of point A at the      Advances in Materials Science and Engineering structure core with different thermal conductivities demonstrates a tendency to rise rapidly and then decrease slowly. e maximum temperature of point A is 49.7°C, 48.2°C, 46.6°C, and 45.5°C correspondingly, all appeared at about 240 hours. e temperature of point B located at 50 mm inside the surface demonstrates a twice process of decrease to increase. After 420 hours, the temperature of point B with bigger thermal conductivity is lower than one with a smaller one. e temperature of surface point C demonstrates a similar change process with point B, but with smaller amplitude. However, the temperature of point C in different thermal conductivity changes to the same value that almost equals to the environment temperature. e temperature at point D at the foot of the concrete structure is almost keeping the same change process at different thermal conductivities because it is mainly determined by the environment temperature. At the same time, the temperature difference between the core and surface of the structure is calculated as 33.1°C, 31.6°C, 29.7°C, and 28.0°C, respectively. From the above analysis, it can be found that the hydration heat has the strongest heating effect in the core region of the structure. e heat is mainly released close to the concrete surface. However, increasing the thermal conductivity of concrete has a positive effect on the thermal stability of the construction for reducing the maximum temperature in the core region of the structure and also decreasing the temperature difference between the core and surface of the concrete foundation. Figure 5 shows the calculated and fitted maximum principal tensile stress at each point with a different thermal conductivity. e principal tensile stress is induced by the action of temperature and self-weight. Due to symmetry, the maximum principal tensile stress of point A is close to zero. Due to the stress relief, the maximum principal tensile stresses at points B and C is all less than allowable principal tensile stress, while the maximum principal tensile stress occurs at point D. Point D is located at the junction of the bedrock, and the structure and the displacement is restrained at the same time; as a result, stress concentration is easy to occur, but it cannot be eliminated in construction.

Effect of ermal Conductivity.
erefore, more attention should be paid to the maximum principal tensile stress in this region. Moreover, as shown in Figure 4, the maximum principal tensile stress at points A, B, and C decreases, while point D increases with the increase of thermal conductivity. Fitting the maximum principal tensile stress of four points with the thermal conductivity shows a linear relationship with the maximum principal tensile stress of the structure and positive correlation in points A, B, and C while negative correlation in point D. Obviously, the tensile stress of concrete interior can be reduced through increasing the thermal conductivity of concrete, and the situation is just opposite in the junction of the bedrock and the structure. Anyway, the maximum principal tensile stress inside the construction does not exceed the tensile strength of concrete with every thermal conductivity. On the contrary, the maximum principal tensile stress is larger than the tensile strength of concrete when the thermal conductivity is bigger than 1.0 W/(m·K), which can cause structural cracks. e maximum principal tensile stress increases 36.7% when the thermal conductivity changes from 0.5 W/(m·K) to 3.5 W/ (m·K). In conclusion, reducing the thermal conductivity of concrete can reduce the risk of structural cracking. erefore, suitable thermal conductivity not only ensures the temperature below the standard threshold but also makes sure the stress state under stable. Some research results [44,45] can be used to realize this target, such as using limestone, lightweight aggregate (expanded shale), recycled, or natural and recycled aggregates to replace basalt, quartzite, siltstone, and other coarse aggregates, adding auxiliary cementitious materials (fly ash and slag) and not too high humidity during casting. Figure 6 shows the relationship between temperature and time with four different specifics heat which are 0.8 kJ/(kg·°C), 0.9 kJ/(kg·°C), 1.0 kJ/(kg·°C), and 1.1 kJ/(kg·°C), respectively. As shown in Figure 6, the temperature of the four points demonstrates the same change process similar to themselves with different thermal conductivities, as shown in Figure 4. Besides, the temperature rises more with bigger specific heat than that with smaller specific heat. However, the temperature differences with the different specifics heat of the same point are smaller than that with different thermal conductivities, which proposed that thermal conductivity has a greater influence on the temperature than specific heat. e maximum temperature of point A is 48 e maximum temperature of the first temperature rise at point C is 13.7°C, 13.9°C, 14.1°C, 14.3°C, and 14.4°C, also appeared around 80 hours. e temperature at point D is almost keeping the same change process with the environment temperature, basically not affected by specific heat. At the same time, the temperature difference between the core and surface of the structure is calculated as 32.7°C, 32.6°C, 32.5°C, 32.4°C, and 32.3°C, respectively, with each specific heat. Obviously, reducing the specific heat can reduce the maximum temperature inside the structure, but increase the temperature difference between the core and surface of the structure. However, the temperature change is very limited, especially when compared with the change brought about by thermal conductivity. Figure 7 shows the calculated and fitted maximum principal tensile stress at each point with a different specific heat. e maximum principal tensile stress of point A is close to zero and points B and C are all less than allowable principal tensile stress, and the maximum principal tensile stress occurs at point D for the same reason discussed in Section 4.1. Moreover, as shown in Figure 6, the maximum principal tensile stress at points A, B, and C increases while point D decreases with the increases of specific heat, all change with a linear relationship. erefore, increasing the specific heat can reduce the maximum principal tensile stress of the construction. e maximum principal tensile stress reduces 6.8% when the specific heat increases from 0.8 kJ/ (kg·°C) to 1.1 kJ/(kg·°C). 6 Advances in Materials Science and Engineering

Advances in Materials Science and Engineering
In conclusion, specific heat increase has a positive effect on hydration temperature rise and a negative effect on maximum principal tensile stress. However, the influence of concrete specific heat on the maximum principal tensile stress is greater than that on the maximum temperature. Under the condition that the hydration heat temperature meets the requirements, it enlightens us to control the maximum principal tensile stress to avoid the structure cracking through increasing specific heat methods, such as adding an appropriate amount of fly ash and slag, reasonably reducing the sand ratio, appropriately increasing the content of small stones under the condition of constant coarse aggregate gradation [46]. Figure 8 shows the relationship between temperature and time with four different surface heat diffusion coefficients which are 18 kJ/(m 2 ·h·°C), 78 kJ/(m 2 ·h·°C), 138 kJ/(m 2 ·h·°C), and 165 kJ/(m 2 ·h·°C), respectively. It can be seen that the surface heat diffusion coefficient has no obvious influence on the temperature in the central concrete structure, such as point  Advances in Materials Science and Engineering

Effect of Surface Heat Diffusion Coefficient.
A. e temperature rise in the central concrete structure is mainly controlled by the thermal conductivity and specific heat. However, the surface heat diffusion coefficient has a more significant impact near the boundary of the structure. As shown in Figure 8, there is an obvious hydration heat temperature rise at points B and C when the surface heat diffusion coefficient equals 18 kJ/(m2·h·°C). e temperature is easily affected by environmental temperature along with the increase of the surface heat diffusion coefficient. e maximum temperature of point A is close to 49.0°C appeared at 340 hours with a different surface heat diffusion coefficient. e temperature difference between the core and surface is 29.0°C, 33.4°C, 34.0°C, and 34.1°C, respectively, with each surface heat diffusion coefficient. erefore, a bigger surface heat diffusion coefficient contributes to more heat loss in the boundary, but it is not conducive to reduce the temperature difference between the core and surface. Figure 9 shows the calculated and fitted maximum principal tensile stress at each point with the different surface heat diffusion coefficient. e maximum principal tensile stress of point A is close to zero due to symmetry. e maximum principal tensile stress of points B and C decreases with the surface heat diffusion coefficient increase because that more temperature stress is relieved with a bigger surface heat diffusion coefficient. However, because point D is constrained by the bedrock, the temperature stress cannot be easily relieved with heat loss, so the maximum principal tensile stress shows an increasing trend with the surface heat diffusion coefficient increase. e maximum principal tensile stress at four points all shows a law of quadratic function.

Advances in Materials Science and Engineering
In conclusion, appropriately reducing the surface heat diffusion coefficient has a positive effect on relieving the maximum principal tensile stress. e maximum principal tensile stress reduces up to 52% when the surface heat diffusion coefficient changes from 165 kJ/(m 2 ·h·°C) to 8 kJ/(m 2 ·h·°C). Since the surface heat diffusion coefficient is related to wind speed, surface roughness, and surface thermal resistance condition [47], measures such as surface insulation, adding additives (such as defoamer) can be taken to reduce the surface heat diffusion coefficient and finally reduce the maximum principal tensile stress and prevent the occurrence of structural thermal cracks. Figure 10 shows the relationship between temperature and time with five different temperature rise coefficients which are 0.20 d −1 , 0.25 d −1 , 0.30 d −1 , 0.35 d −1 , and 0.40 d −1 , respectively. It can be seen that the temperature rise coefficient has a significant impact on the first hydration heat temperature rise process whether in the core region or near the boundary of the structure, except for the foot point D.

Effect of Temperature Rise Coefficient.
e maximum temperature of point A is 48.2°C, 48.7°C, 49.0°C, 49.2°C, and 49.4°C, respectively, appeared at 420 hours, 380 hours, 340 hours, 320 hours, and 280 hours with the corresponding temperature rise coefficient. e temperature difference between the core and surface is 31.3°C, 32.1°C, 32.6°C, 32.9°C, and 33.2°C, respectively. It is obvious that reducing the temperature rise coefficient can reduce the maximum temperature and also reduce the temperature difference between the core and surface of the structure by changing the rate of temperature rise in the condition of the same hydration heat generated. Figure 11 shows the calculated and fitted maximum principal tensile stress at each point with a different temperature rise coefficient. e maximum principal tensile stress of four points with a different temperature rise coefficient shows a similar change regulation with that with a different surface heat diffusion coefficient, and the maximum principal tensile stress at four points also shows a law of quadratic function with the temperature rise coefficient. e foot points of the structure, including point D, are also the positions of stress concentration and the maximum principal tensile stress which has exceeded the allowable stress of the concrete if the temperature rise coefficient is greater than 0.30 d −1 .
In conclusion, appropriate decrease of the temperature rise coefficient has a positive effect on relieving the maximum principal tensile stress. e maximum principal tensile stress can reduce 18.9% when the temperature rise coefficient changes from 0.40 d −1 to 0.20 d −1 . Measures such as controlling pouring temperature and reducing the amount of cement [48] can be taken to reduce the temperature rise coefficient and decrease the maximum principal tensile stress in the result.

Effect of Solar Absorption Coefficient.
e thermal parameters analyzed above have not considered the influence of the solar absorption coefficient, which was set to zero. However, studies [42,49] found that the temperature field of the concrete structure is greatly affected by solar radiation. When calculating the radiant heat of the flat surface of a concrete structure, the annual variation of radiant heat ΔF and the annual average radiant heat ΔT [1] are usually calculated as follows: where A s is the yearly amplitude of radiant heat, r is the solar absorption coefficient discussed in this section, and S is the solar radiation on cloudy days, which is calculated according to the solar radiation heat S 0 on sunny days. e calculation equation is given as follows: where k is the coefficient, and n is the cloud cover. In this study, S 0 equals 924.5 kJ/(m 2 ·h), n equals 0.1, and k equals 0.668. Figure 12 shows the relationship between temperature and time with six different solar absorption coefficients which are 0, 0.4, 0.5, 0.6, 0.7, and 0.8, respectively. e zero solar absorption coefficient is a contrast study condition. As shown in Figure 12, the solar absorption coefficient has a great impact on the temperature near the boundary of the structure but almost does not influence the core regions. e temperature arises generally linear along with the time at points A, B, and C. Also, the bigger solar absorption coefficient induced the higher temperature rise at these three    points. e maximum temperature of point A is close to 49.0°C appeared at about 340 hours with the corresponding solar absorption coefficient. e temperature difference between the core and surface is 32.6°C, 26.3°C, 24.3°C, 22.3°C, 20.4°C, and 18.4°C, respectively. It is because that more heat is induced by bigger solar absorption coefficient absorb by the surface and then against the internal heat dissipation. erefore, it is demonstrated that the temperature difference between the core and surface reduces as the solar absorption coefficient increases. Figure 13 shows the calculated and fitted maximum principal tensile stress at each point with a different solar absorption coefficient. It can be got that the maximum principal tensile stress of the study points all decrease to a certain degree when the solar absorption coefficient increases. However, in the matter, the maximum principal tensile stress in the structure is no more occurred at point D, but at point C which is located at the surface of the structure.
is conclusion just explains the common physical weathering degradation phenomenon of the construction structure. e tensile stress values at all points are less than the allowable tensile stress. Fitting the maximum principal tensile stress with the solar absorption coefficient shows a quadratic function law.
In conclusion, increasing the solar absorption coefficient can reduce the tensile stress of the concrete foundation. e maximum principal tensile stress can reduce 21% when the solar absorption coefficient changes from 0 to 0.8. Because the solar absorption coefficient of the structure surface is related to the surface color [50], measures such as the dark coating of the surface formwork or using dark insulation can play a major role in increasing the surface solar absorption coefficient.

Effect of ermal Expansion Coefficient.
e thermal expansion coefficient is a thermal parameter which not directly impact heat transfer but significantly influences thermal stress. Figure 14 shows the calculated and fitted maximum principal tensile stress at each point with a different thermal expansion coefficient. When the thermal expansion coefficient of concrete changes from 8 * 10 −6 /°C to 12 * 10 −6 /°C, the maximum principal tensile stress at   e main reason is that under unconstrained conditions, the free temperature deformation is given as follows: where α is the thermal expansion coefficient.
Equation (23) shows that the bigger the thermal expansion coefficient, the higher the deformation of the structure and also the higher stress. However, the maximum principal tensile stress at point D shows an opposite change rule because when the thermal expansion coefficient changes from 8 * 10 −6 /°C to 12 * 10 −6 /°C, the maximum principal tensile stress of points B and C increases almost 50%, and the value has quickly approached point D. is shows that the restraint of the foundation has a certain release by stress increase of the free surface, but it releases little, so the maximum principal tensile stress of the foundation is reduced by only 2%.

Conclusions
Aiming to analyze the influence of thermal parameters on the temperature and thermal stress distribution of the foundation, six thermal parameters are chosen and discussed in this study. e main conclusions are listed as follows: (1) Increasing the thermal conductivity of concrete and reducing the specific heat and temperature rise coefficient can reduce the maximum temperature of the structure. Other thermal parameters have no obvious effect on the maximum temperature. (2) Increasing the specific heat, solar absorption coefficient, or thermal expansion coefficient has a positive effect on reducing the maximum principal tensile stress, but on the contrary of the effect of the thermal conductivity, surface heat diffusion coefficient, and temperature rise coefficient. Moreover, it is found that fitting the maximum principal tensile stress at different positions of the structure shows a linear function with thermal conductivity, specific heat, and thermal expansion coefficient and a quadratic function with surface heat diffusion coefficient, temperature rise coefficient, and solar absorption coefficient. (3) Combined with the research results, the following temperature control and crack prevention measures are proposed under the condition of ensuring the concrete strength, such as reducing the amount of cement, increasing the particle size of coarse aggregate, and selecting coarse aggregate with a high thermal expansion coefficient.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request. 14 Advances in Materials Science and Engineering