1. Introduction
Some concrete structures need to be urgently repaired because of sudden damage, such as pipeline leakage and traffic road damage, which requires a short time and high timeliness. Calcium sulfoaluminate cement (CSA) has the characteristics of fast hardening, early strength, high corrosion resistance, and high permeability resistance [
1], and is considered to be a potential rapid repair engineering material. Some scholars have used additional components to further speed up the hydration rate and improve the ultra-early strength of CSA. Gypsum can improve the early hydration rate of CSA, and at a low dose, it can effectively improve the early compressive strength and reduce the drying shrinkage. By contrast, with a dose that is too high, the later strength of the hardened cement paste will decline [
2]. Lithium salts make it possible for CSA to skip over the hydration induction period and directly enter the hydration acceleration period, thus improving the early hydration rate and hydration heat release [
3,
4,
5]. However, an excess dose of lithium salts will affect the later compressive and flexural strength of cement. In addition, some scholars [
6,
7,
8] have explored the effects of mineral admixtures on the early hydration behavior, mechanical properties, and shrinkage performance of CSA.
However, the above studies are only from the perspective of additional components to improve the hydration rate and ultra-early mechanical properties of calcium sulphoaluminate cement, but its shortcomings of low alkalinity, poor bonding properties, and poor development continuity of long-term mechanical properties need to be solved from the perspective of mineral phase composition design. Alite-ye’elimite-belite-ferrite cement (AYBFC) [
9,
10,
11,
12], which has come into being in recent years, not only has the characteristics of CSA, but also possesses the advantages of Portland cement, such as high alkalinity, high bonding properties due to the formation of more gel hydration products, the stable development of long-term mechanical properties, etc. Therefore, AYBFC is very suitable for rush repair and construction.
AYBFC can be prepared by various methods. It is an effective method to use C
3S mineral as the seed to induce more C
3S to form in CSA; for example, the 7 wt.% C
3S seed can induce 13 wt.% new C
3S to form in CSA [
10], but it is very difficult to use this method for the actual production of AYBFC. The AYBFC clinker has been successfully calcined by the technology of barium ion doping and liquid phase control [
11,
12], and the cement has been produced by some companies [
13]. When the gypsum dosage is 15 wt.%, the AYBFC reaches the highest compressive strength [
12].
However, the effects of additives commonly used in CSA on AYBFC have not been reported yet. This study aims to probe into the effects of Li2CO3 and superplasticizer on the ultra-early strength of AYBFC to put forward an improvement method for its ultra-early strength, expecting to provide a path for a better application of AYBFC in rush repair and construction works.
2. Materials and Methods
2.1. Raw Materials
In this study, AYBFC produced by Shandong Linqu Shengwei Special Cement Co., Ltd., Weifang, China, was adopted, which was composed of 15 wt.% gypsum and 85 wt.% clinker., with its clinker phase analysis in
Figure 1, its clinker mineral composition quantitatively analyzed by using the method of Rietveld refinement shown in
Table 1, and its basic properties shown in Reference [
12]. The model of Li
2CO
3 used in the experiment was MACKLIN L812282, with a purity of 99.5%. The polycarboxylate superplasticizer used was produced by Jiangsu SBT New Materials Co., Ltd. (Nanjing, China). The sand used in this experiment was ISO standard sand produced by Xiamen ISO Standard Sand Co., Ltd. (Xiamen, China), and the water used was tap water.
2.2. Experimental Methods
(1) Water requirements of normal consistency, setting time, and compressive strength.
The water requirements of normal consistency and setting time were tested in accordance with GB/T1346-2011 [
14]. The raw materials were weighed according to the mix proportion in
Table 2, and the cement paste was stirred evenly by an NJ-160A cement paste mixer, quickly put into a 20 mm × 20 mm × 20 mm cubic mold, tamped and vibrated on a vibration table, taken down and scraped, and marked. Finally, the mold was put into a constant-temperature (20 ± 2 °C) and -humidity (>95%) curing chamber for curing for 30 min, 1 h, and 4 h, respectively. Subsequently, the sample was taken out and demolded, and its compressive strength was determined via a CMT5505 microcomputer control electron universal testing machine.
(2) Instrumental analyses.
The phase analysis of hydration products was performed by the D8-ADVANCE X-ray diffractometer of German Brooke Company (Saarbrücken, Germany). The hydration rate and hydration heat were tested by a TAM Air eight-channel isothermal microcalorimeter produced by Retrac HB Company (Stockholm, Sweden). The SEM was tested by a German ZEISS (Oberkochen, Germany) EVOLS15 scanning electron microscope.
3. Results and Discussion
3.1. Effects of Li2CO3 and Superplasticizer on Setting Time and Ultra-Early Strength of AYBFC
It can be seen from
Figure 2 that both the initial and final setting time of AYBFC were accelerated with the increase of Li
2CO
3 content within a certain range of dosage. The initial and final setting time reduced from 16 and 22 min to about 4 and 6 min, respectively, when the dosage of Li
2CO
3 increased from 0.00 wt.% to 0.06 wt.%. The results indicated that the setting time of AYBFC could be accelerated by adding Li
2CO
3. When the Li
2CO
3 content was 0.05 wt.%, the initial and final setting time were about 5 and 8 min. After adding 0.35 wt.% polycarboxylate superplasticizer, the initial and final setting time increased to about 12 and 18 min, indicating that the polycarboxylate superplasticizer had the effect of delaying the setting time.
It can be seen from
Figure 3 that the ultra-early compressive strength of AYBFC increased at first and then decreased with the increase in the content of Li
2CO
3. When the content of Li
2CO
3 was 0.05 wt.%, the compressive strength of AYBFC reached the highest value, and its compressive strength at 30 min, 1 h, and 4 h reached 4.67, 9.10, and 22.49 MPa, respectively, which were 498.7%, 348.3%, and 85.9% higher than that of the blank sample. This meant that the ultra-early compressive strength of AYBFC was significantly improved by an appropriate amount of Li
2CO
3, which was because of the very strong accelerating effect of Li on the start of the reaction [
15]. This has already been reported in several studies for CSA [
16] and for calcium aluminate cement [
17,
18,
19,
20].
On the above basis, 0.35 wt.% superplasticizer was co-doped with 0.05 wt.% Li
2CO
3, which markedly improved the strength of AYBFC at different ages. Specifically, the compressive strength at 30 min, 1 h, and 4 h were 101.1%, 58.7%, and 62.1% higher than that of the sample only doped with 0.05 wt.% Li
2CO
3. The doping of the superplasticizer inhibited the hydration of AYBFC, but it facilitated the electrostatic repulsion of the cement particles, and the water molecules wrapped by the cement particles were released, improving the fluidity of the slurry, reducing the water consumption, compacting the matrix [
21], and further enhancing the compressive strength.
3.2. Effects of Li2CO3 and Superplasticizer on Micro-Composition and Structure of AYBFC
3.2.1. Hydration Analysis
AYBFC has four exothermic peaks [
12]. Except the first exothermic peak caused due to heat released by dissolution when C
4A
3$, C
3S, and dihydrate gypsum came in contact with water, which was not easily observed because of the overlap, the other exothermic three peaks of the blank sample can clearly be seen in
Figure 4. The second and third exothermic peaks were caused by the hydration reaction of ye’elimite (anhydrous barium calcium sulphoaluminate and C
4A
3$, collectively referred to as C
4A
3$ in this study). The fourth exothermic peak was a comprehensive exothermic peak mainly related to C
3S. Compared with the blank sample, the four exothermic peaks of A5 and A7 all appeared in advance due to the presence of Li
2CO
3, and were nearly combined into one exothermic peak. It can be seen from
Figure 5 that the hydration rate and early hydration heat release of AYBFC were the fastest due to 0.05 wt.% Li
2CO
3, but, by contrast, if 0.35 wt.% superplasticizer was doped, the hydration rate and hydration heat release of AYBFC were slowed down. This was consistent with the experimental results of the setting time, which was associated with the inhibitory effect of superplasticizer on the cement hydration reaction and the action mechanism for the generation of hydration products [
22,
23].
3.2.2. XRD and SEM Analysis
It can be seen from
Figure 6 that the diffraction peaks of clinker mineral phases C
4A
3$, C
3S, C
2S, and cement admixture gypsum were very clear in the A0 spectrum of the blank sample at 30 min of hydration, but without apparent AFt (ettringite; its chemical formula is 3CaO·Al
2O
3·3CaSO
4·32H
2O) diffraction peaks of hydration products, indicating a quite low hydration degree. By contrast, clear AFt diffraction peaks of samples A5 and A7 were observed, showing that the hydration of AYBFC was promoted by both the single doping of Li
2CO
3 and co-doping of Li
2CO
3 and superplasticizer. Comparing the images in
Figure 7, it can be seen that almost no needle- or rod-like AFt was generated in the blank sample A0 due to the low hydration degree, and the hardening body was discontinuous with many pores. A large number of AFts were produced in samples A5 and A7; in particular, those in A5 were needle- or rod-shaped, being both large and thick, which was helpful to improve the ultra-early strength, but disadvantageous to the later strength [
16]. The AFt in A7 was needle-shaped with a relatively small size. In addition, the matrix compactness of the samples could be clearly observed and sorted as A7 > A5 > A0, which was consistent with the results of compressive strength.
As shown in
Figure 8 and
Figure 9, after hydration for 4 h, the diffraction peaks of the clinker mineral phase and gypsum in each sample decreased, while the AFt diffraction peak increased clearly, indicating that the hydration degree of each sample increased clearly; in particular, the AFt diffraction peak of sample A5 was the sharpest, followed by sample A7, which was also consistent with the results of the hydration rate. At this time, many AFts had been formed in the blank sample, but the matrix was still loose. Many gel products had been produced in samples A5 and A7, which wrapped the AFt to form a continuous structure, and the matrix was relatively compact. Evidently, the matrix compactness of A7 was the highest.
4. Conclusions
(1) An appropriate amount of Li2CO3 can significantly improve the ultra-early compressive strength of AYBFC. At the dose of 0.05 wt.%, the compressive strength of AYBFC reached the highest value, and its compressive strength at 30 min, 1 h, and 4 h increased by 498.7%, 348.3%, and 85.9%, respectively, compared with that of the blank sample.
(2) If 0.35 wt.% superplasticizer was co-doped with 0.05 wt.% Li2CO3, the strength of AYBFC at each age was markedly enhanced, and its compressive strength at 30 min, 1 h, and 4 h was 101.1%, 58.7%, and 62.1% higher than that of the sample only doped with 0.05 wt.% Li2CO3.
(3) The ultra-early compressive strength of AYBFC was improved most clearly by co-doping Li2CO3 with superplasticizer. First, an appropriate amount of Li2CO3 could promote the hydration of AYBFC and the early generation of hydration products. Second, the superplasticizer could inhibit the hydration reaction of the cement and the generation of hydration products, and it could strengthen the matrix compactness, which was beneficial for the development of strength.
Author Contributions
Investigation, methodology, formal analysis, writing—original draft, P.D.; investigation, methodology, writing—review and editing, H.S.; investigation, methodology, formal analysis, X.L. and Y.H.; investigation, methodology, funding acquisition, project administration, writing—review and editing, X.C. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by the National Natural Science Foundation of China Regional Innovation and Development Joint Fund (Grant No. U22A20126), the Taishan Scholars Program (Grant No. tsqn202312210), and the “111 Center”.
Data Availability Statement
Data are contained within the article.
Conflicts of Interest
Author Hao Sun was employed by the company Shandong Luqiao Building Materials Co., Ltd. The remaining 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.
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