Shrinkage and Strength Properties of Coal Gangue Ceramsite Lightweight Aggregate Concrete

It is a promising and effective method for waste treatment by using coal gangue to make lightweight aggregate concrete. However, lightweight aggregate concrete with low-density coal gangue ceramsite is prone to cracking during volume shrinkage, which limits its application in the construction industry. In an attempt to resolve the problem of cracking in shrinkage, this study investigated the effect of prewetting time and shrinkage reducing agents on shrinkage volume and concrete strength through a series of concrete shrinkage and strength tests.*e experimental results show that shrinkage volume reduced at a prewetting time of 12 hrs or with a 2% addition of D-230 polyether amine reductant.With the optimal conditions of 12 hrs prewetting time and 2% addition of the reductant, the concrete shrinkage volume significantly decreased with a negligible impact on its strength. Appropriate amount of shrinkage reducing agent and adjustment of prewetting time of coal gangue ceramsite are necessary to reduce the shrinkage rate and improve the stability of the specimen. *is is of great significance to wide application of lightweight aggregate concrete with coal gangue ceramsite.


Introduction
Coal gangue is a kind of solid waste generated by the coal mining and washing. Long-term storage not only takes up space but also causes serious pollution and destruction of the surrounding environment [1][2][3]. e treatment and utilization of coal gangue has attracted the interest of many researchers [4] since the 1970s. Coal gangue has been widely used for power generation, the extraction of chemical products, and the creation of chemical fertilizers and ceramsite [5][6][7][8][9].
Coal gangue can be converted into low-density ceramsite aggregates, which can be used to make low-density coal lightweight aggregate concrete, usually with an apparent density <1950 kg/m [10]. ere are three types of coal gangue ceramsites (CGC): self-igniting coal gangue, burning coal gangue, and coal gangue mixed with binder [11]. Utilizing coal gangue to make CGC instead of natural, ordinary aggregate can reduce coal gangue disposal and lead to a significant reduction in the consumption of natural aggregates in the construction industry.
Compared with ordinary concrete, lightweight aggregate concrete has many attractive characteristics, such as lower density, higher strength, better antiseismic performance, and so on [12]. Many studies have been conducted on the preparation and expansion behavior of this concrete (the densities not exceeding 1950 kg/m 3 ) in the presence of additives including carbon fiber, waste materials [13,14], and reductants [15][16][17][18][19][20][21]. However, owing to the high water absorption and porosity, large volume shrinkage of lightweight aggregate concrete causes the formation of cracks. ese cracks connect to flow paths for gases, water, and aggressive substances. It is harmful for the durability and compromise of the performance of concrete structures [13].
is limits its application in the construction industry to a large extent. Many attempts to tackle this problem have been made in LWAC. For reefs aggregate, Cheng et al. [22] studied the drying shrinkage behavior of the concrete with different moisture contents. It is found that increasing the moisture content significantly reduced its shrinkage rate and the concrete made of saturated reef aggregates showed good performance in reducing autogenous shrinkage. For saturated lightweight aggregate, Henkensiefken et al. [23] studied the effect of the amount of cementitious material on LWAC shrinkage and found that specimens with larger volume fractions of SLWA reduced its shrinkage rate. For fly ash-clay ceramsite, Wang et al. [24] studied the effect of ceramsite prewetting on LWAC autogenous shrinkage by using microstructural analysis of the concrete and found that moisture content had influence on the shrinkage but was not dominant. For the shale ceramsite, Gong et al. [25] verified that the presence of a reductant can reduce the drying shrinkage and autogenous shrinkage of the concrete, thus mitigating the cracking issue. ese studies have shown that adjusting the prewetting time or addition of a certain amount of reductant can effectively suppress shrinkage of the concrete. However, for coal gangue ceramsite, systematic tests on wetting time and shrinkage reducing agents have not been reported in any prior study. ree problems remain: (1) the lack of a quantitative relationship between CGC prewetting time and concrete shrinkage, (2) the lack of a quantitative relationship between the amount of SRA used and concrete shrinkage, and (3) the lack of a quantitative understanding of the combined effect of lightweight aggregate prewetting time and SRA amount on volume shrinkage and concrete strength.
e present study is conducted to fill these research gaps by investigating shrinkage and strength properties of coal gangue ceramsite lightweight aggregate concrete. A series of concrete shrinkage and strength tests were undertaken for different CGC prewetting times and SRA doses, separately.
rough these experiments, the effects of CGC prewetting time and SRA on concrete shrinkage and strength will be analyzed, and the results will provide effective guidance for solving the concrete shrinkage problem.

Materials Preparation.
Ceramsite is a main component of coal gangue ceramsite lightweight aggregate concrete and accounts for approximately 50% of its total volume. Its properties have significant influence on the performance of the concrete. e coal gangue ceramsite used in this study was produced by Chaoyang Hualong Kejian Co., Ltd, and its morphology is shown in Figure 1. is product has similar physical characteristics and particle size distribution to ordinary concrete, as seen in Tables 1 and 2, respectively. It is widely used for concrete testing experiments. JEEFMINE ® D-230 polyether amine, with an average molecular weight of approximately 230, was used as a reductant. Limestone sand with a particle size ranging from 0.15 mm to 2.34 mm was used as a fine aggregate. Tap water was used in all experiments. In this study, the dose of the added reductant ranged from 0.5% to 1.0% while the watercement ratio ranged from 15% to 20%. e fraction of the coal gangue ceramsite with a particle size ranging within 9.5∼16 mm was 87.8% (see Table 2), which meets the standard requirements for concrete materials (ASTM C330/C330M). e cement used was P • O • A32.5 grade slag Portland cement. Its physical properties and chemical composition are shown in Tables 3 and 4, respectively.
e compressive strength at 28 d was 40.1 MPa, as shown in Table 3, and the loss on ignition was 1.06%, as shown in Table 4. e physical properties of the cement in terms of strength, chemical composition, and loss on ignition meet the quality requirements laid out in GB175-2007 entitled "General Portland Cement" and also meet the test requirements.

Design of Mixing Proportions for LWAC and CGC.
In JGJ12-2006, which is entitled "Technical Regulations for Lightweight Aggregate Concrete Structure," the strength grade for structural LWAC is specified. In this test, LWAC was designed with compressive strength grade LC30. e initial mixing proportions are in Table 5.
e following experiments are adjusted on the basis of the proportions.

LWAC Mixing and Curing.
In the LWAC mixing process, the following stirring procedures were applied: first stir the cement, ceramic, and fine aggregate evenly, and then add the appropriate amount of water and superplasticizer ( Figure 2). e mold size was 100 mm × 100 mm × 515 mm, and the mixture well mixed by hand was placed in the mold to vibrate for 120 s; after 24 h, it was stripped for standard curing, and finally, the test was performed. Similarly, the following CGC prewetting procedure was followed: weigh the CGC; immerse the CGC in water for a certain period of time; drain the water to keep the saturated surface dry; and vibrate the mixture for 60 s. e specimens were cured at a temperature of 20 ± 2°C and immersed in a saturated solution of Ca(OH) 2 . en, concrete performance tests were carried out according to the GBT50081-2002 standard.   Advances in Materials Science and Engineering

Compressive Strength Test for LWAC.
e test machine was an NYL-200D. e instructions were as follows: place the specimen in the center of the lower press plate, keeping the center of the specimen in line with the center of the press plate ( Figure 3). Start the press with the lower surface of the press plate facing upward. When the specimen is close to the upper plate and the upper pressure surface is in contact with the balanced test body, apply a uniform continuous load at a loading rate of 0.6 ± 0.1 MPa. When the deformed specimen is close to destruction, stop adjusting the throttle of the press, and continue to load until destruction. en, record the failure load. e compressive strength of LWAC was calculated as follows:

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where f cu denotes the compressive strength of LWAC, MPa; F represents the specimen failure load, N; and A is the specimen bearing area, mm 2 . F and A are readily measured experimentally. From equation (1), the compressive strength for the test specimen size can be calculated. However, it must be noted that the product of this value and the size conversion factor (set to 0.95 in this study based on the standard set in GBT 50082-2009) is the final compressive strength for the standard size concrete.

Shrinkage Experiment for LWAC.
e LWAC shrinkage test comes from GBT 50082-2009 entitled "ordinary concrete long-term performance and durability test method standards." After the specimen is modeled, it should be cured for 24 ± 2 h with a membrane (Figure 4). e specimen's initial length (L 0 ) is measured by an HSP-540 contraction expansion instrument, and then the specimen is placed in an environment in which the temperature is 20 ± 3°C and the humidity is 60 ± 5% at the proper time point to measure the specimen's length (L t ).
e resolution for the length measurement is 0.01 mm. e shrinkage rate for the specimen is calculated by using the following formula: where ε st is the shrinkage rate of the concrete at time t, t is the time elapsed after the initial length is measured, days; L b is the measured gauge of the specimen, that is, the distance between the inner sides of the concrete specimen, mm; L 0 is the initial length of the specimen, mm; and L t is the length of the specimen measured at t, mm. e shrinkage rates for the three specimens are averaged to calculate the shrinkage rate for the group, and the resolution of the final shrinkage rate is approximately 1.0 × 10 −6 .

Effect of CGC Prewetting Time on Volume Shrinkage of LWAC.
Five sets of LWAC were prepared according to the reference mixture proportions (see Table 5 for the mixture proportions). e selected prewetting times for the ceramsite are 0 h, 1 h, 6 h, 12 h, and 24 h. ree specimens were formed for each concrete test set. After the specimens were molded for 1 d, they were demolded, and their initial length was determined according to the GBT 50082-2009 method.
ereafter, the shrinkage and strength of the specimens were measured at 1 d, 3 d, 7 d, 14 d, 28 d, and 56 d.
As seen from Figure 5, the shrinkage of LWAC develops gradually. LWAC shrinkage increases with time. Early on, the slope of the curve is large, indicating that the LWAC shrinkage rate is maximal. In the later stage, the LWAC shrinkage tends to level off. For example, the shrinkage rate for concrete at 3 d is more than 70% of the shrinkage rate at 28 d.
It can be seen from Figure 6 that the shrinkage rate for LWAC decreases as the CGC prewetting time increases, but this decrease is not constant. When the prewetting time goes from 0 h to 1 h, the shrinkage rate at 56 d (in Figure 6(b)) decreases by approximately 25 × 10 −6 mm/mm, while when the prewetting time goes from 12 h to 24 h, the shrinkage rate at 56 d (in Figure 6(b)) decreases by only approximately 9 × 10 −6 mm/mm. is is because CGC water absorption increases rapidly in the early flooding stage, and the absorption rate reaches 5.07% at 1 h. However, when the ceramsite is almost fully saturated after 12 h, the water absorption rate for the ceramsite is only 0.38%. erefore, the described approach is an effective way to reduce the drying shrinkage of LWAC for longer prewetting times because the prewet ceramsite contains a certain amount of water, and some of the water is gradually released in the late hydration process; thus, the relative humidity decreases slowly to compensate for the shrinkage. However, when the prewetting time exceeds 24 h, the moisture content of the CGC has negligible variation, and the effect of the prewetting time on the shrinkage reduction rate is insignificant. Figure 7 shows that the prewetting time improves the mechanical resistance at 14 and 28 d, and the only decrease is observed when the test is performed early (at 7 d).

Effect of CGC Prewetting Time on the Strength of LWAC.
is improvement is probably because the strength of the concrete and the cement stone depends on the interfacial adhesion of the aggregate and the cement stone. e denser the interface area of the structure, the greater the cohesive force and, hence, the higher the strength of the concrete. is trend probably also originates from a deficiency in the LWAC preparation due to a minor operation error. At 7 d, as the moisture content of the CGC increases from 0 to 7.43% (from C0 to C4), its ability to absorb moisture from the cement slurry decreases, resulting in a decrease in the watercement ratio at the interface. e larger the water-cement ratio at the interface is, the greater the porosity is, so the early strength decreases. At 28 d, with the further progression of the hydration reaction, the internal humidity of the cement slurry gradually decreases. e water return capacity increases with an increase in the prewetting time, so the cement in the interface area can be fully hydrated. is causes an increase in the density of the interface structure, so the compressive strength at 28 d increases. As seen in Figure 8, with an increase in the degree of ceramsite prewetting, the strength growth rate for LWAC also increases. e growth rate for LWAC (C0) prepared with dry ceramic is 17.5%, while the growth rate for LWAC (C4) is 35.9%.
In the results of the preceding analysis, it can be seen that the strength of the LWAC decreases at a certain rate in the early stage after CGC prewetting, and the internal curing effect on the prewet ceramsite enhances its strength. is enhancement will increase with the degree of prewetting.

Effect of SRA on the Volume Shrinkage of LWAC.
In the experiment, five groups of LWAC were prepared by adjusting the dose of SRA (0%, 0.5%, 1.0%, 2.0%, and 4.0% of the cement mass, respectively): the groups are denoted as C0, D1, D2, D3, and D4, respectively. e initial length of the specimens was determined by the GBT 50082-2009 method, and then the shrinkage was calculated at the following time points: 1 d, 3 d, 7 d, 14 d, 28 d, and 56 d.
It can be seen in Figure 9 that the addition of SRA considerably reduces the shrinkage of LWAC. With an increase in SRA, the LWAC shrinkage decreases gradually for each sample time point. For example, the shrinkage rates at 14 d, 28 d, and 56 d for C1 are approximately 79%, 82%, and 79% of those for C0. In the case of C1, when the concentration of water is approximately 1.3%, the cement paste internal capillary solution for the surface tension drops significantly, thereby reducing the negative pressure inside the gap and reducing the shrinkage of the specimen.
However, the shrinkage rate for LWAC instead decreases with an increase in SRA content. As shown in Figures 10(a) and 10(b), the shrinkage rate for LWAC is influenced by the amount of SRA, which decreases monotonically with decreasing slope. A slower shrinkage reduction rate beyond 2% can be seen in both graphs. When SRA content increases from 2.0% to 4.0%, the shrinkage at 3 d decreases by approximately 6%, and the shrinkage at 56 d decreases by 3%. is slower reduction after the 2% dose can be explained by the reduction of the solution surface tension. When SRA makes up over 2.0% of the cement, its concentration in the water is more than

3.4.
Effect of SRA on LWAC Strength. As described above, five different percentages of SRA (0%, 0.5%, 1%, 2%, and 4%) were used in the construction of the cement test groups. ree sets of samples were prepared in each test group. After 1 d of stripping, they were placed in saturated Ca(OH) 2 solution. According to the methods of GB/T 50081-2002 "Test method of mechanical properties of ordinary concrete," the compressive strength was measured at 7 d, 14 d, and 28 d. en, the compressive strength of the concrete was measured. Figure 11 illustrates that the SRA mixture has an adverse effect on the compressive strength of LWAC. With an increase in SRA, the compressive strength of LWAC gradually decreases. Compared to the reference group (0% SRA), the compressive strength for LWAC with 2% SRA decreases by 6% and 3% at 7 d and 28 d, respectively. When the SRA dose increases to 4%, the compressive strength of the concrete decreases significantly, by 10% and 5% at 7 d and 28 d, respectively. is is consistent with Rajabipour's study [26], which suggested that when the SRA dose is less than 2%, there is no adverse effect on strength, whereas the strength of the concrete is reduced when SRA is increased to 5% of the cement content.

Combined Effect of SRA and Prewetting Time on LWAC
Shrinkage. Figure 12 presents the conditions in which a combination of 2.0% SRA and different prewetting times (0 h, 1 h, 6 h, and 24 h) are used. Based on the similar curve trends with and without SRA, shrinkage suppression can mainly be attributed to prewetting. It should be noted that,     since the relative ratio of water to cement in the experiment is 0.4%, the concentration in the water is approximately 5.0% with 2% SRA, indicating an increasing concentration of SRA. erefore, tension is reduced a small amount, which is able to prevent significant shrinkage. Figure 13 displays a similar decreasing trend with respect to the prewetting time for the shrinkage rate in both scenarios. When the prewetting time extends from 0 to 1 h, the shrinkage rate decreases markedly. However, when the prewetting time extends from 1 h to 12 h, the variation in the shrinkage rate is subtle. e difference in shrinkage variation after 1 h can be clearly seen in the two graphs. e case without SRA has a relatively larger reduction compared to the other case.
More quantitatively, the shrinkage (mm/mm) for C0, C1, C2, and C4 (in Figure 13(a)) at 56 d was 497 × 10 −6 , 473 × 10 −6 , 463 × 10 −6 , and 449 × 10 −6 . Compared with the lightweight aggregate C0 reference, the shrinkage (mm/mm) of C1, C2, and C4 decreased by 24 × 10 −6 , 34 × 10 −6 , and 48 × 10 −6 , respectively. However, after the addition of SRA (in Figure 13(b)), the shrinkage (mm/mm) for D3, E1, E2, and E3 at 56 d was 368 × 10 −6 , 348 × 10 −6 , 343 × 10 −6 , and 338 × 10 −6 , respectively. Compared with the initial state of D3, the shrinkage (mm/mm) for E1, E2, and E3 produced a reduction of 20 × 10 −6 , 25 × 10 −6 , and 30 × 10 −6 , respectively. It can be seen that, after the induction of shrinkage and with the incremental change in prewetting, the result is not as pronounced as when internal curing alone is applied. is difference is probably due to the inclusion of SRA in the LWAC, which reduces the capillary solution surface tension. In the case where ceramsite water absorption is constant and the capillary diameter in the semisaturated state remains constant, the smaller the surface tension of the pore solution, the smaller the corresponding capillary tension drop. us, lower surface tension weakens the effects of shrinkage inhibition. is speculation remains to be confirmed in later research.
In this experiment, the effect of SRA on the shrinkage of LWAC under different dose conditions is also studied by using water-treated coal gangue ceramic. e water saturation time was 24 h, and SRA concentrations of 0%, 0.5%, 1.0%, and 2.0% were selected for evaluation.
From Figures 14 and 15, it can be seen that the shrinkages (mm/mm) of D1, D2, and D3 at 56 d were 409 × 10 −6 , 381 × 10 −6 , and 369 × 10 −6 , respectively, when dry ceramic was used. ese values are approximately 82%, 77%, and 74% of that seen in the reference group C0. When saturated ceramsite was used, the shrinkages (mm/   mm) of E4, E5, and E3 were 382 × 10 −6 , 351 × 10 −6 , and 338 × 10 −6 , respectively. ese shrinkages are 85%, 78%, and 75% of those in reference group C4. Compared with the addition of SRA alone, as shown in Figure 15(a), the combined incorporation of SRA and prewetting of the ceramic, as shown in Figure 15(b), significantly reduces LWAC shrinkage. However, the effect of SRA increase on the drying shrinkage is not obvious, and the shrinkage rate in Figure 15(b) is lower than its counterpart in Figure 15(a).
In summary, compared with the prewetting of the ceramic or SRA alone, the use of both SRA and prewet ceramic composite together can significantly inhibit LWAC shrinkage, resulting in a significant "superposition" effect.

Combined Effect of SRA and Prewet Ceramic on LWAC
Strength. Figure 16 displays the effect of SRA, prewetting time, and the combination of the two on the compressive strength of LWAC under dry curing conditions. In the early hydration stages, SRA and the internal curing compound have an unfavorable effect on LWAC strength, but it is smaller at the later stage and is slightly higher than that of the reference group C0. At the same SRA dose, compared with SRA alone, the use of prewet ceramsite results in higher LWAC strength. is increased strength is mainly due to the internal curing of ceramsite. e dense structure of the cement slurry interface area increases the concrete strength and ultimately compensates for the loss of strength caused by SRA-induced delay of cement hydration. In the combined case, with elapsed prewetting time, the late strength is enhanced to a certain extent.
In addition, at 7 d, the LWAC strength in the combined case is lower than that in the reference group. However, the degree of reduction is much smaller than the sum of the drops observed when using SRA and internal curing individually. is result may be due to the addition of SRA. Under this condition, the shrinkage stress of the cement slurry decreases, and this decreased stress reduces the formation of microcracks and other defects, finally reducing the adverse effect on the strength. However, with an increase in SRA content, LWAC strength decreases, which indicates that the internal curing effect from prewetting the ceramic cannot completely eliminate the negative effect of SRA on strength when the SRA content is too large.

Conclusions
In this study, the prewetting time of coal gangue ceramsite and shrinkage reducing agent were taken into account by laboratory experiments. e effects of the prewetting time and shrinkage reducing agent on the shrinkage volume and mechanical properties of LWAC are discussed. e results showed that prewetting time and shrinkage reducing agent have great influence on the shrinkage of lightweight aggregate concrete with coal gangue ceramsite. Appropriate control of prewetting time and shrinkage reducing agent in the sample preparation can increase strength of LWAC to meet the concrete strength standard and considerably reduce the shrinkage of concrete.
As prewetting time of CGC is prolonged, shrinkage volume of LWAC gradually decreases. For example, when ceramsite is initially prewetted, the shrinkage volume reduction is most notable. When CGC is prewetted for more than 12 h, the effect of prewetting time on shrinkage volume reduction becomes insignificant. In addition, prewetting time also shows influence on strength. For example, after CGC prewetting treatment, the early strength (at 7 d) of LWAC decreases. e late strength of LWAC increases and becomes higher than that without prewetting treatment. e incorporation of SRA has a significant effect on shrinkage volume reduction of LWAC. For example, when SRA is 2% of the cement, shrinkage volume of LWAC at 56 d is reduced by approximately 26%. When the SRA dose is large, an increase in the dose has less effect on shrinkage volume reduction. In addition, addition of SRA has an adverse effect on the compressive strength of LWAC. For example, when SRA makes up 2% or less of the cement, the effect of SRA on the compressive strength of the LWAC is small. When the dose increases to 4% of the cement, LWAC strength decreases significantly. e compressive strength decreases by 10% and 5% at 7 d and 28 d, respectively. e combined application of SRA and prewetting shows good and pronounced suppression of LWAC shrinkage. Specifically, the combined application has a certain influence on the early strength of LWAC. e late strength of the concrete enhances and effectively compensates for the adverse effect of SRA on strength.
Operation error in the preparation of LWAC, i.e., not mixing sufficiently, probably contributed to shrinkage and strength changes. e adverse effect of this operation error remains to be assessed and improved. It is suggested that the effect of different methods on the lightweight aggregate concrete with coal gangue ceramsite be presented by microstructure analysis. It can reveal the microscale mechanism of the dependence of concrete strength on prewetting time and shrinkage reducing agent.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. Advances in Materials Science and Engineering 9