Study on Mechanical Properties of PET Fiber-Reinforced Coal Gangue Fine Aggregate Concrete

Huang, Yanlin; Zhou, An

doi:https://doi.org/10.1155/2021/6627447

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Research Article | Open Access

Volume 2021 | Article ID 6627447 | https://doi.org/10.1155/2021/6627447

Study on Mechanical Properties of PET Fiber-Reinforced Coal Gangue Fine Aggregate Concrete

Yanlin Huang¹and An Zhou¹

Academic Editor: Bin Gong

Received30 Nov 2020

Revised16 Dec 2020

Accepted21 Dec 2020

Published05 Jan 2021

Abstract

In recent years, with the rapid development of the construction industry, the demand for natural river sand has become increasingly prominent. Development of alternatives to river sand has become an interesting direction for concrete research. In this paper, coal gangue was proposed to replace part of the river sand to produce coal gangue fine aggregate concrete, while waste polyethene terephthalate (PET) bottles were used as raw materials to make PET fibers to improve the mechanical properties of coal gangue fine aggregate concrete. There were two parts of the test conducted. In the first part, the compressive strength of the gangue fine aggregate concrete cube, splitting tensile strength, axial compressive strength, and static elastic modulus were studied when the substitution rate of coal gangue increased from 0% to 50%. Referring to the equation of the full stress-strain curve of plain concrete, the stress-strain constitutive equation of coal gangue fine aggregate concrete was analyzed and studied. By comparing with plain concrete, it was found that the coal gangue concrete with a replacement rate of 50% had higher compressive strength and tensile strength, but its brittleness was significantly greater than that of plain concrete in the later stage. In the second part, by studying the effect of different PET fiber content on the mechanical properties of coal gangue fine aggregate concrete with a replacement rate of 50%, it was found that when the addition of PET fiber was 0.1% and 0.3%, not only were compressive strength, splitting tensile strength, static elastic modulus, and flexural strength of the gangue fine aggregate concrete effectively improved but also the brittleness of concrete can be significantly reduced. The study found that after adding 0.3% PET fiber, the coal gangue fine aggregate concrete with a replacement rate of 50% has better mechanical properties and less brittleness.

1. Introduction

Coal gangue is a kind of solid waste with low carbon content and hard texture produced in the process of coal mining [1]. In the long-term coal production process, China has deposited about 5 billion tons of coal gangue, and it is still increasing rapidly at a rate of about 200 million tons per year [2–4]. If a large amount of coal gangue cannot be used reasonably and efficiently, not only will a large amount of mountains and farmland be occupied, causing serious environmental pollution and resource waste, but also it is easy to cause natural disasters such as fires and mudslides [4, 5]. Coal gangue contains a certain amount of active SiO₂ and Al₂O₃ [6], and its main chemical composition is similar to a natural aggregate [7, 8], indicating that coal gangue can be used as a substitute for a concrete fine aggregate [2]. The active SiO₂ and Al₂O₃ in cement can produce secondary hydration reaction with cement to further improve the microstructure of concrete [9, 10]. Coal gangue instead of a natural aggregate for concrete production is an interesting research field. Scholars domestically and internationally have done some related research in this field and achieved certain results, which have made great contributions to promoting the application of coal gangue in the construction field. For example, adding a certain amount of fine coal gangue to cement can significantly increase the slump and pumpability of the cement [11], but when the amount of fine coal gangue in the cement gangue backfill increases from 40% to 60%, the strength of the cement coal gangue backfill decreases with the increase in the fine coal gangue content [12]. Li et al. applied the cleaned and crushed coal gangue material to the railway subgrade and found that the dynamic stiffness K30 of the coal gangue was greater than 130 MPa·m^-1, which met the requirements of high-speed railway subgrade [13]. Zhang et al. [14] found that the particle size distribution of the coal gangue coarse aggregate has limited influence on the mechanical properties of concrete. When coal gangue is used to replace all concrete coarse aggregates, the compressive strength of coal gangue coarse aggregate concrete was reduced by 19.4% compared with that of plain concrete. As the percentage of coal gangue replacement increases, the axial compression failure mode of coal gangue coarse aggregate concrete will change from shear failure to longitudinal split failure [8]. When studying the influence of coal gangue calcination temperature, calcination time, and fineness modulus on the mechanical properties of concrete, Dong et al., Yang et al., and Wang and Zhao found that the gangue fineness modulus is 1.9, and when the calcination temperature is 700°C, the gangue is fine. Aggregate concrete mortar has the highest compressive strength [4]; coal gangue is calcined at a temperature of 750°C for 10 minutes, and the 28d compressive strength of coal gangue aggregate concrete is about 39% higher than that of natural coal gangue concrete [15]. When the gangue aggregate Fuller gradation curve index () is 0.62, the porosity of concrete is the lowest and the density is the highest. The compressive strength of 28d coal gangue aggregate concrete can reach 37 MPa, which meets the strength requirements of C30 ordinary concrete [16]. Qiu et al. [17] studied the influence of coal gangue coarse aggregate replacement rate on concrete freeze resistance and established a CGC freeze-thaw damage evolution model. They found that when the coal gangue replacement rate is less than 40%, CGC can better meet the freeze. It is required that the freeze-thaw damage evolution model is in good agreement with the actual experimental data, which can effectively reflect the freeze-thaw damage development process of CGC in the freeze-thaw environment. However, Guan et al. [18] found that when the gangue replacement rate increased from 0% to 60%, the frost resistance of coal gangue concrete was significantly reduced, and the physical and mechanical properties of coal gangue concrete decreased with the extension of the freeze-thaw cycle time [19]. At the same time, Luo et al. [20] studied the influence of steel fiber content and shape on the compressive strength and split tensile strength of coal gangue concrete after freezing and thawing. They found that when the volume of corrugated steel fiber is 1%, the compressive and tensile strength of the coal gangue concrete decreases the least after freezing and thawing. After freezing and thawing, the reduction in compressive and tensile strength is the smallest. Wang et al. [21] found that the water-cement ratio, sand ratio, and steel fiber content have a certain effect on the brittleness of coal gangue ceramsite lightweight aggregate concrete. When the water-cement ratio and sand ratio are greater than 0.32 and 0.38, the brittleness increases with the decrease in the water-cement ratio and sand ratio, and when the steel fiber content is less than 1.5%, the brittleness decreases with the increase in the steel fiber content.

By consulting domestic and foreign research literature, it is found that the current research is mainly concentrated on coal gangue aggregate concrete. The related research focused on the mechanical properties of coal gangue fine aggregate concrete and how to further improve the basic mechanical properties and toughness of coal gangue fine aggregate concrete. There is little and no application of PET fiber in coal gangue fine aggregate concrete. In order to analyze and study the effect of PET fiber on the mechanical properties of coal gangue fine aggregate concrete, we have conducted relevant understanding of PET materials by reading literature and other methods. It was discovered that PET is a compound polymer with strong corrosion resistance, fatigue resistance, and flexural properties. If a large number of PET packaging products cannot be recycled well, it is not only a waste of resources but also serious environmental pollution [22, 23]. Processing PET packaging products into fibers to make PET fiber concrete not only can increase the utilization rate of PET but also has a certain effect in improving the mechanical properties of concrete. Related research is as follows: Pereira et al. [24] studied the influence of length and content of fiber on the mechanical properties of concrete and found that when the volume ratio of PET was 0.2%, the concrete tensile strength decreased with the increase in PET length. When the length was increased from 10 mm to 20 mm, the concrete tensile strength decreased by 3.09 MPa. Moreover, the incorporation of PET can enhance the compressive strength of concrete, which is similar to the results of Irwan et al. [25]. At the same time, the research results of Pereira et al. also showed that with the addition of 0.1% and 0.2% PET fibers, the compressive strength of concrete increased by about 15% and 10%, respectively. But Nematzadeh et al. [26] processed PET material into fragments to replace part of the river sand and found that the compressive strength of concrete would be reduced. The research results of Jawad et al. [27] showed that PET powder was ground into powder and added to GFRP steel bars. It was found that PET powder can be used as a strength additive to increase the compressive strength of the reinforced concrete. Blanco et al. [28] studied the effect of replacing part of river sand with different amounts and shapes of PET materials on the electrochemical properties of steel bars in concrete and found that the samples with PET had a higher potential value than the control. Ochi et al. [29] studied the influence of fiber content on the workability and compressive strength of concrete under different water-cement ratios. It was found that when , the compressive strength of concrete was about 13.8% higher than that of ordinary concrete after adding 1% of PET. 0.3% of PET can increase the workability of concrete and PET. Taghreed and Mohammed [30] added PET fiber to the concrete beam and found that the failure mode of the concrete beam changed from shear to bending. When the volume of PET fiber was 1%, the shear capacity of the reinforced concrete beam increased by 11.1%, And when the PET content is 1.25%, the direct shearing capacity is increased by 43.5%. But Khalid et al. [31] found that adding PET fiber to concrete does not significantly change the failure mode of reinforced concrete beams but only improves the results of the first crack load. Alani et al. [32] found that adding 1% PET fiber to concrete can increase the flexural strength of GUHPPCC beams by about 63.24% compared with 90-day-old ultra-high-performance concrete, and adding PET fiber can significantly improve the bending resistance and ductility of GUHPPCC flat panel. The research results of Al-Hadithi et al. [33] also showed that the incorporation of PET fiber into the SCC board can significantly improve the energy absorption capacity of the board and increase the compressive strength and flexural strength of the SSC board. At the same time, Fadadu et al. [34] found that compared with plain concrete, PET concrete exhibits higher ductility under cyclic loading. However, Mohammed et al. [35] found that the addition of PET fiber could not improve the ultimate bearing capacity of concrete beams but only improved the crack resistance of the beams. Through the above research results, it can be found that the reasonable use of PET materials in the concrete field can improve some physical properties of concrete to a certain extent.

The purpose of this experiment is to develop a new type of concrete by taking the place of concrete fine aggregate with coal gangue and optimizing with recycled PET fiber. The test includes two parts: the first part mainly studied the influence of coal gangue replacement rates of 10%, 20%, 30%, 40%, and 50% on the compressive strength, splitting tensile strength, axial compressive strength, and static elastic modulus. In the second part, in order to reduce the brittleness of concrete, three groups of coal gangue fine aggregate concrete with different amounts of PET fiber were designed to study the effect of the amount of PET fiber on the mechanical properties and brittleness of the concrete. Finally, the relationship between split tensile strength and axial compressive strength and the relationship between axial compressive strength and cubic compressive strength were discussed and analyzed. The research results showed that the coal gangue replacement rate of 50% had better mechanical properties and less brittleness after adding 0.3% PET fiber.

2. Test Material and Method

2.1. Test Material

In this paper, the P.O42.5 ordinary Portland cement produced by China Huaxin Co., Ltd. was adopted, and its chemical composition complies with China’s GB175-2007 standard [36]. The coarse aggregate was crushed with a continuous grading mechanism, the particle size range is 5-25 mm, and the water absorption rate is 1.81%. The fine aggregate is natural river sand, and the fineness modulus is 2.92; the moisture content and the water absorption rate are 2.51% and 7.58%, respectively. Both the coarse aggregate and the fine aggregate meet the requirements of the Chinese GB50086-2001 standard [37]. The water used for mixing and curing is local drinking water with a pH value of 6.7 and a chloride and sulfate content of 250 mg/L, which meets the Chinese JGJ 63-2006 standard [38]. The coal gangue used in this experiment was produced at the Woyang Mineral Processing Plant in Lingshou County, China, and its diameter ranges from 2 to 4 cm. In order to make coal gangue stones into coal gangue fine aggregates, the coal gangue stones were firstly crushed with a jaw crusher; then, coal gangue particles with a diameter less than 4.75 mm were screened by using a vibrating sand screen, and finally, the coal gangue fine aggregate with a fineness modulus of 3.42 was manually made, as shown in Figure 1. The PET materials come from bottles of China Resources C’estbon Beverage Co., Ltd., which were hand-cut into PET fibers with a length of 14-16 mm and a width of 3-5 mm, and they were washed and dried (Figure 2).

2.2. Test Method

This study mainly includes two parts: first, a preliminary evaluation of the effect of replacing part of river sand with coal gangue and then a series of tests on PET fiber-reinforced coal gangue concrete. According to the Chinese GB/T 50081-2002 standard [39], the concrete test block for the first part of the test was made into two kinds of size of and , in which the cube specimen was used to test cube compression and split tensile strength and the prism specimen was used for axial compression test and static pressure modulus test (Figure 3). At the same time, in order to draw the axial compressive stress-strain curve of concrete, it is necessary to use a displacement meter to collect the vertical deformation of the prism specimen (Figure 4). In the second part, in order to study the effect of PET fiber on the flexural properties of concrete, the flexural test of concrete was conducted on the specimen with the size of (Figure 5); other tests were the same as the first part. All the specimens need to be cured for 28 days in an environment with a temperature of and a relative humidity more than 95% in advance.

3. Test Design and Results of the First Part

In order to study the impact of coal gangue on the mechanical properties of concrete, six fine aggregate replacement rates of 0%, 10%, 20%, 30%, 40%, and 50% were designed in the first part of the experiment. The detailed mixing ratio is shown in Table 1.

3.1. Cube Compressive Strength and Split Tensile Strength

36 cube specimens were equally divided into two parts to carry out the compressive test and split tensile strength test, respectively, whose variation is shown in Figure 6.

As shown in Figure 6, when the gangue replacement rate changed from 10% to 40%, the compressive strength of concrete cubes first decreased and then increased with the increase in the gangue replacement rate, which was smaller than that of plain concrete. When the replacement rate increased from 40% to 50%, the compressive strength was increased by 8.7% compared to that of plain concrete, which is mainly because SiO₂ in coal gangue can promote the secondary hydration reaction of cement and the calcium silicate produced made the interior of the concrete more compact [40]. At the same time, because of the high water absorption rate of coal gangue, the water-cement ratio of concrete decreased with the increases in the replacement amount of coal gangue, and appropriately reducing the water-cement ratio can increase the strength of concrete [41]. The splitting tensile strength of CGC tended first to decrease and then increase with the increase in coal gangue replacement rate. When the coal gangue replacement rate was 50%, the CGC tensile strength reached the highest value of 3.8 MPa, which was about 1.2 times that of plain concrete. T1he main reason is similar to the compressive strength of the CGC cube.

3.2. Axial Compressive Strength and Static Elastic Modulus

36 prism specimens were equally divided into two parts to carry out the axial compression test and static compression elastic modulus test, respectively. At the same time, in order to more directly reflect the influence of the coal gangue replacement rate on the static elastic modulus of concrete, the elastic modulus of each group of the gangue fine aggregate concrete was compared with the elastic modulus of the plain concrete with a 0% replacement rate; their variation trend is shown in Figure 7.

As shown in Figure 7, the axial compressive strength of concrete decreased first and then increased with the increase in coal gangue replacement rate. When the replacement rate of coal gangue was 10%~40%, the axial compressive strength was smaller than that of plain concrete. When the replacement rate increased from 40% to 50%, the compressive strength of concrete significantly increased and was greater than that of plain concrete, and the main reason was similar to the compressive strength of concrete cubes. When the replacement rate of coal gangue increased from 10% to 50%, the elastic modulus of concrete was lower than that of plain concrete. When the replacement rate reached 50%, the elastic modulus was the smallest. At the same time, as the axial compressive strength of coal gangue fine aggregate concrete increased, its elastic modulus decreased continuously; this is contrary to the characteristic that the elastic modulus of plain concrete increases with the increase in compressive strength. The main reason is that the texture of coal gangue is soft, with the increase in the coal gangue replacement rate; the number of hard river sand particles decreased, resulting in a relatively large deformation of CGC when the concrete was subjected to equivalent pressure changes. According to the elastic modulus calculation (Equation (1)), when the pressure value of () remained unchanged, the larger the , the smaller the elastic modulus. where is the elastic modulus of concrete, is the load when the stress equals to 1/3 of the axial compressive strength, is the initial load when the stress is 0.5 MPa, is the gauge distance, is the bearing area of the specimen, and is the deformation difference when the specimen is loaded from to .

3.3. Axial Compressive Stress-Strain Curve

The study of the axial compressive stress-strain curve of specimens includes three main steps. First, measure the vertical compression variable and relative pressure value of the concrete; then, calculate the stress and strain of the concrete by Equation (2); finally, the stress and strain of coal gangue fine aggregate concrete were processed in a dimensionless manner by using and ( and represent the peak stress and peak strain, respectively; and represent the real-time stress and real-time strain, respectively) [42, 43], and the stress ratio and strain ratio were calculated. The processing results are shown in Figure 8. where is the stress, is the strain, is the axial compression (MPa), is the area of the compression surface of the specimen (mm²), is the vertical compression variable (mm), and is the vertical height of the original test piece (mm).

As shown in Figure 8, when the coal gangue replacement rate increased from 10% to 50%, the stress-strain curve of the rising section of CGC fitted well with that of ordinary concrete, indicating that in the elastic and elastoplastic stage, the deformation mechanism of CGC was similar to that of plain concrete. However, the descending curve of CGC was relatively scattered. When the replacement rate was 50%, the downward trend was the steepest and the brittleness increased sharply. When the replacement rate was 10% and 20%, the curve trend of CGC basically coincided with that of plain concrete. At the same time, it can be seen from Figure 8 that the stress-strain curve of CGC was similar to that of ordinary concrete; they all gone through the stages of elasticity, elastoplasticity, and yield failure [43]. Therefore, the approximate constitutive equation of CGC can be established according to the equation of full stress-strain curve of plain concrete [42, 43] (see Equation (3)). Through nonlinear fitting analysis, it was found that when and , the stress-strain constitutive equation of CGC was basically consistent with the experimental data. Therefore, and can be used as the value of parameter of the stress-strain constitutive equation of coal gangue fine aggregate concrete. The fitting curve of the axial compressive stress-strain constitutive equation of coal gangue fine aggregate concrete can be obtained, as shown in Figure 9. where is the stress ratio, is the strain ratio, and and are the parameters of the curve equations of concrete rising and falling sections, respectively, where , in which and are the secant elastic modulus at 0.5 and at peak stress, respectively; the value range of is generally , and the value range of is generally [44, 45].

4. Test Design and Results of the Second Part

In the first part of the test, it was found that when the replacement rate of coal gangue was 50%, the cubic compressive strength, axial compressive strength, and splitting tensile strength of coal gangue fine aggregate concrete were all higher than those of plain concrete, but after the compressive strength and splitting tensile strength reached the peak point, the compressive and tensile properties in the later period dropped sharply. The brittleness of plain concrete increased significantly, which did not meet the low brittleness requirements of the Chinese GB50010-2010 specification [46–54]. However, adding an appropriate amount of fiber to concrete can enhance the strength and ductility of the concrete. Therefore, in the second part, based on the coal gangue fine aggregate concrete with a replacement rate of 50%, three groups of coal gangue fine aggregate concrete with different PET fiber content of 0.1%, 0.3%, and 0.5% were designed, respectively, to study the effect of PET fiber content on the mechanical properties and brittleness of coal gangue fine aggregate concrete. The concrete mix ratio is listed in Table 2.

4.1. Cube Compressive Strength and Split Tensile Strength

By conducting the compressive test and split tensile test on 24 cube specimens, the cubic compressive strength and split tensile strength of PET fiber-reinforced coal gangue fine aggregate concrete increased with the increase in PET fiber. The change trend chart is shown in Figure 10.

As shown in Figure 10, when the amount of PET fiber was 0.1% and 0.3%, the cubic compressive strength and splitting tensile strength were both higher than those of CGC-5. When 0.1% PET fiber was added, the cubic compressive strength and split tensile strength were increased by 7.2% and 7.9%, respectively, and increased by 13.1% and 32.2% compared to those of the plain concrete in Figure 6. However, when the amount of PET fiber increased from 0.3% to 0.5%, the cubic compressive strength and split tensile strength of coal gangue fine aggregate concrete showed a downward trend, which was 9.1% and 26.3% lower than those of CGC-5.

4.2. Axial Compressive Strength and Static Elastic Modulus

By conducting the axial compression test and testing static elastic modulus of 24 prism specimens, the trend of the axial compressive strength and relative elastic modulus of PET fiber-reinforced coal gangue fine aggregate concrete was obtained and is shown in Figure 11.

As shown in Figure 11, when the PET fiber content was 0.1%, the axial compressive strength and relative elastic modulus of concrete increased by 3.2% and 19.2%, respectively, compared with those of CGC-5. When the amount of PET fiber was 0.3%, the axial compressive strength of concrete was equal to that of CGC-5, but when the amount of fiber reached 0.5%, the axial compressive strength of concrete decreased to be 8.9% lower than that of CGC-5. At the same time, when the amount of PET fiber was 0.1%~0.5%, the relative elastic modulus of concrete was larger than that of CGC-5. It can be seen that PET fiber can increase the elastic modulus of concrete.

4.3. Flexural Strength

In order to study the effect of PET fiber content on the flexural performance of concrete, three groups of coal gangue fine aggregate concrete with different PET fiber content were designed. In the flexural test, the change trend of the flexural strength of PET fiber-reinforced coal gangue fine aggregate concrete with the increase in PET fiber and the pressure-displacement curve of concrete were obtained, as shown in Figures 12 and 13.

As shown in Figure 12, the flexural strength of concrete increased first and then decreased with the increase in PET fiber content. The addition of 0.3% PET fiber can effectively increase the flexural strength of coal gangue fine aggregate concrete, which is 6.7% higher than that of CGC-5. However, when the fiber content increased from 0.3% to 0.5%, the compressive strength of concrete was reduced by about 8.1% compared with that of CGC-5. At the same time, it can be found from Figure 13 that with the increase in the PET fiber, the slope of the pressure-displacement curve continuously decreased, which indicated that PET fiber could obviously improve the ductility of coal gangue fine aggregate concrete before the concrete was broken. Among them, the 0.5% fiber-reinforced coal gangue fine aggregate concrete had the largest displacement of 1.87 mm, which was 2.56 times that of CGC-5.

4.4. Axial Compressive Stress-Strain Curve

While studying the influence of different amounts of PET fiber on the axial compressive stress-strain curve of coal gangue fine aggregate concrete, the test data was processed by the method in the first part of the test, and the full curve of the axial compressive stress-strain of PET fiber reinforced coal gangue fine aggregate concrete and the fitted curve of the stress-strain constitutive equation were obtained and are shown in Figures 14 and 15.

As shown in Figure 14, when the amount of PET fiber was 0.1%, 0.3%, and 0.5%, the slope of the descending section of the stress-strain curve was gentler than that of CGC-5, and the descending slope of CGC-0.3 was the gentlest. It can be seen that PET fiber can significantly reduce the brittleness of coal gangue fine aggregate concrete, and the reduction effect of 0.3% fiber content was the best. At the same time, through the nonlinear fitting analysis of the full stress-strain curve of concrete, it was found that when and , the axial compressive stress-strain constitutive equation is basically consistent with the test data. It can be seen that and can be used as the parameters of the stress-strain constitutive equation of PET fiber-reinforced coal gangue fine aggregate concrete.

5. Correlation Discussion

5.1. The Relationship between Split Tensile Strength and Axial Compressive Strength

After analyzing the relationship between the split tensile strength and axial compressive strength of concrete, the linear equations of the split tensile strength and axial compressive strength of coal gangue fine aggregate concrete and PET fiber-reinforced coal gangue fine aggregate concrete were obtained in Equations (4) and (5), respectively. The relationship between the split tensile strength and axial compressive strength is drawn in Figure 16. where is the splitting tensile strength (MPa) and is the axial compressive strength (MPa).

As shown in Figure 16, the splitting tensile strength of concrete presented a positive linear relationship with the axial compressive strength. The determination coefficient of coal gangue fine aggregate concrete was equal to 0.6522, which was much smaller than 0.9875 of PET fiber-reinforced coal gangue concrete, which indicated that PET fiber had an obvious influence on the linear relationship between split tensile strength and axial compressive strength.

5.2. The Relationship between the Cube Compressive Strength and the Axis Compressive Strength

By analyzing the relationship between the cube compressive strength and the axial compressive strength, the linear equations for the compressive strength and axial compressive strength of the coal gangue fine aggregate concrete and PET fiber-reinforced coal gangue fine aggregate were obtained in Equations (6) and (7), respectively. The relationship between the cubic compressive strength and the axial compressive strength is drawn in Figure 17. where is the axial compressive strength (MPa) and is the cubic compressive strength (MPa).

As shown in Figure 17, the cubic compressive strength of concrete was positively proportional to the axial compressive strength, and the determination coefficient of the linear equation was greater than 0.8, indicating that the linear equation fitted the actual data well.

6. Conclusions

(1)Through studying the influence of replacing part of river sand with coal gangue on compressive performance, tensile performance, and static elastic modulus of concrete, it was found that with the increase in the coal gangue replacement rate, the concrete cube compressive strength, the split tensile strength, and the axial compressive strength showed a trend of increasing first and then decreasing, while the static elastic modulus showed a decreasing trend. But when the replacement rate of coal gangue was 50%, the cubic compressive strength, split tensile strength, and axial compressive strength of concrete reached their maximum values, which were, respectively, 5.2%, 22.6%, and 13.7% higher than those of plain concrete. At the same time, when discussing the correlation between concrete axial compressive strength and cubic compressive strength, the axial compressive strength and the cubic compressive strength showed a linear relationship with the determination coefficient of 0.8131(2)When analyzing the stress-strain curve of coal gangue fine aggregate concrete, it was found that when the replacement rate of coal gangue was 10%, 20%, and 30%, the axial compressive stress-strain curve of coal gangue fine aggregate concrete was similar to that of plain concrete. Through fitting analysis, we found when and , the fitting curve obtained according to the standard concrete stress-strain curve equation was basically consistent with the test data of CGC. By taking the values and as the parameters of the CGC stress-strain constitutive equation, the stress-strain constitutive equation of CGC which is similar to that of concrete can be obtained, and they both included stages of elasticity, elastoplasticity, and yield failure. However, when the coal gangue replacement rate was 40% and 50%, the descending section of the curve of concrete was steeper, and its brittleness was significantly greater than that of plain concrete(3)When studying the effect of PET fiber content on the mechanical properties of coal gangue fine aggregate concrete, it was found that after adding 0.1% PET fiber, the cubic compressive strength, splitting tensile strength, axial compressive strength, and flexural strength of concrete are increased by 7.2%, 7.9%, 3.2% and 19.2%, respectively, compared with those of CGC-5. However, when the content of PET fiber increased to 0.5%, the cubic compressive strength, split tensile strength, axial compressive strength, and flexural strength of concrete decreased, which were, respectively, 9.3%, 26.3%, 8.9%, and 8.1% lower than those of CGC-5. When the amount of PET fiber increased from 0.1% to 0.5%, the static elastic modulus of concrete was higher than that of CGC-5. When the amount was 0.1%, the static elastic modulus increased the most, which was 19.2% higher than that of CGC-5. It can be seen that by adding 0.1% or 0.3% of PET fiber in the coal gangue fine aggregate concrete with a replacement rate of 50%, the mechanical properties of the concrete can be improved and the brittleness of the concrete was reduced(4)According to the axial compressive stress-strain curve of PET fiber-reinforced coal gangue fine aggregate concrete, it can be found that the addition of 0.1%, 0.3%, and 0.5% of PET fiber can significantly reduce the brittleness of the concrete, and the result of the 0.3% fiber was the best. When and , the axial compressive stress-strain constitutive equation of PET fiber-reinforced coal gangue fine aggregate concrete was basically consistent with the experimental data. It can be seen that and can be used as the parameters of the stress-strain constitutive equation of PET fiber-reinforced coal gangue fine aggregate concrete(5)In the discussion of the correlation of concrete mechanical properties, it was found that the splitting tensile strength of PET fiber-reinforced coal gangue fine aggregate concrete had a linear relationship with the axial compressive strength, the determination coefficient was 0.9875, and the axial compressive strength and the cubic compressive strength also showed a linear relationship with the determination coefficient of 0.9327. Through comparative analysis with the linear equation of coal gangue fine aggregate concrete, it was found that PET fiber has a significant effect on the linear relationship between split tensile strength and axial compressive strength

Data Availability

The data used to support the findings of this study are included within the article.

Conflicts of Interest

The authors declare that there are no conflicts of interest regarding the publication of this paper.

Acknowledgments

This research was supported by the Research Fund for High Level Talents of Hubei University of Technology (Grant No. 337173).

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Copyright © 2021 Yanlin Huang and An Zhou. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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