Study on Properties of Waste Concrete Powder by Thermal Treatment and Application in Mortar
1
School of Materials Science and Engineering, Shandong Jianzhu University, Jinan 250101, China
2
Collaborative Innovation Center of green building of Shandong Province, Jinan 250101, China
*
Author to whom correspondence should be addressed.
Appl. Sci. 2020, 10(3), 998; https://0-doi-org.brum.beds.ac.uk/10.3390/app10030998
Submission received: 31 December 2019
/
Revised: 26 January 2020
/
Accepted: 27 January 2020
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Published: 3 February 2020
(This article belongs to the Special Issue Application of Biomass Ashes in Cement-Based Materials)
Abstract
:Waste concrete must be crushed, screened, and ground in order to produce high-quality recycled aggregate. In this treatment process, 15–30% waste concrete powder (<0.125 mm) can be generated. Hydration activity and the reuse of waste concrete powders (WCPs) were studied in this work, and the results illustrated that the particle size changed after a series of thermal treatments at temperatures from 400 ℃ to 800 ℃. The particle size of waste concrete powder decreased by 700 ℃ thermal treatment, and by 600 ℃ thermal treatment, it increased. More active elements appeared in WCP heated by 800 ℃. Nevertheless, the activity index (AI) of WCP, measured by the ratio of mechanical strengths between mortar with a 30% replacement of the cement with WCP and normal mortar without WCP, indicated that the WCP by 700 ℃ thermal treatment had an optimal AI value, which meant WCP treated at 700 ℃ could be used in mortar or concrete as an admixture.
1. Introduction
Due to the large volume of construction and demolition wastes and the deficiency of natural resources, the recycling of building material wastes is urgent and of great importance. The use of building material wastes in concrete can realize up-recycling for building materials.
Concrete wastes can rarely be reused as recycled aggregate to prepare concrete because recycled aggregates “contaminated” with cement paste have lower mechanical properties owing to the presence of cement paste. The workability, mechanical strength, and durability of recycled concrete are adversely affected by recycled aggregate [1,2,3]. Many experiments were carried out to enhance the quality of recycled aggregate, e.g., incorporation of thermal and mechanical treatment [4] and carbonation treatment to strengthen the recycled aggregates [5,6].
In the process to treat the recycled aggregate, some fine powders including cement paste, sand, and coarse aggregate powder are produced, and some studies focused on the quality improvement and application. Increasing the particle size of recycled cement powder with 450 ℃ treatment and partially replacing the cement powder with ground-granulated blast-furnace slag could effectively improve the quality of recycled cement [7]. Xuan and Shui [8,9] reported that new calcium silicate hydrate (C-S-H) was formed and the optimum temperature was at 700–800 ℃. Splittgerber and Mueller reported that clinker could be reproduced from cement paste by 1450 ℃ thermal treatment [10]. The waste concrete powder (WCP) contained not only cement paste powder but also the fine and coarse aggregate powders; therefore, it had a relatively complicated composition and special properties. It was expected that WCP could be simply used in concrete as an admixture.
Admixture is a material other than water, aggregates, hydraulic cement, and fiber reinforcement that is used as an ingredient of concrete or mortar and is added to the batch immediately before or during its mixing [11]. In addition, optimal packing can be achieved with some admixtures as finer fillers, concrete absorptivity, and porosity can be reduced, and concrete has a more watertight structure [12]. Admixtures are classified as active mineral admixtures and inert ones [13], where active mineral admixtures are referred to those that contain latent active SiO2 or Al2O3, e.g., fly ash, slag, and silica fume. Inert mineral admixtures include no latent active compositions, e.g., CaCO3 powder. The use of powders as admixtures in mortar or concrete is judged by standards. On the basis of the stipulation of ASTM C618, cement mortar replaced with 20% admixture as cement can generate greater than or equal to 75% of the strength of the reference mortar (without the replacement of cement) at both ages of 7 and 28 days to be regarded as pozzolanic material [14]. Chinese standards have similar requirements for different admixtures; for example, in Chinese standard JG/T 486, the ratio of mechanical strengths at 7 days and 28 days between mortar with 30% powders replaced with cement and mortar without powders is regarded as an index to judge if a mineral powder can be used as a concrete admixture [13]; another method to determine the pozzolanic activity of an admixture is the Frattini test according to BS EN 196-5:2011 [15,16].
The use of WCP as admixtures in mortar has rarely been investigated. Kim et al. reported that the flow ability and the mechanical strength of mortar used WCP as admixtures decreased, and WCP was certified as a nonreactive powder [17]. Bordy et al. confirmed that cement paste contained 24% reactive residual anhydrous clinker, and the compressive strengths of mortar with 24% cement paste replacing cement decreased; however, the compressive strength of mortar with 20% cement paste replacement could attain 83% of that of the reference specimen [18]. Zhu et al. reported that WCP containing unhydrated cement particles could be used, in part, to substitute the silica fume or cement as a reactive powder in concrete [19]. Although WCP contained cement paste, unhydrated cement particles in cement paste are related to the water/cement (w/c) ratio of concrete; the lower the w/c, the most likely the presence of unhydrated cement particles in concrete.
In the process of thermal treatment, chemical reactions, e.g., hydration water release, C-S-H decomposition, and crystal transfer, occurred in concrete; especially, an active material, larnite (β-C2S), was generated at temperatures of 600–900 ℃ [20,21,22], which meant active materials could appear in the heated WCP. The property change of WCP and the use in mortar as an admixture were investigated in this study.
2. Materials, Methods, and Procedure
The samples were obtained from the used concrete made before 2015. The cement P.O 42.5 was produced by the Shandong Shanshui cement company. The polycarboxylate plasticizer was produced by the Huadi technology company and could reduce water by 37%. The standard sand was bought from Xiamen AisiO in China.
The used concrete was produced with calcium carbonate as aggregates, and was dealt with by crushing, screening, and grinding. The chemical composition of WCP is shown in Table 1.
It could be demonstrated that the chemical ingredients of WCP were similar to those of the cement P.O 42.5. Many calcium oxides existed because the used concrete was produced with calcium carbonate as aggregate. The particle size of WCP was mainly distributed in the range from 0.84 to 30 μm (Figure 1), similar to the cement particle size.
WCP was dealt with by thermal treatments of 200, 400, 600, 700, and 800 ℃ for 3 h in a labor heating furnace. Three 40 × 40 × 160 mm mortar cuboids for every sample were produced with the cement replaced by 30% thermally treated WCP according to the recipe in Table 2; then, its mechanical property and activity index were mainly measured according to the Chinese standard GB/T 17671 [23] and JG/T 486 [13]. In addition, heat flow change was measured by differential scanning calorimetry (DSC), and the mass loss, content of free calcium oxide, and particle size change of WCP by the thermal treatment were investigated. The crystalline structure and morphology of WCP were gauged by X-ray diffraction (XRD) and scanning electron microscopy (SEM), respectively, in order to further prove the effect of the thermal treatment for the property change of WCP.
The mechanical properties were measured by the compression and folding experiment machine made by the SANS company. The content of free calcium oxide was measured by the FC-6 digital free calcium oxide machine made in Shanghai, and, in this test, ethylene glycol was used to react with free calcium oxide, which resulted in the change in liquid conductivity. The free calcium oxide was measured because the machine could gauge the liquid conductivity. The laser particle size analysis machine made by Winner of Jinan gauged the sample size. Other testing devices, such as a mixer and grinding machine, were used in this study too.
Activity index (AI) is the ratio between the mechanical strengths of the concrete, whose 30% cements were replaced by a powder and those of the reference concrete according to the Chinese standard JG/T486 [13].
AI = Fa / Fb × 100%.
AI―activity index in %; Fa―7 and 28 day strength of concrete with 30% replacement of cement by an admixture in MPa; Fb―7 and 28 day strength of reference concrete in MPa.
According to the requirement of Chinese GB/T 486, if the AI meets the values in Table 3, the powder can be regarded as an admixture used in concrete.
3. Results
3.1. Properties of WCP by Thermal Treatment
DSC detection can explain the heat change of WCP in the process of thermal treatment (Figure 2), where a big endothermic peak occurred at temperatures from about 700 to 900 ℃ because of decomposition of calcium carbonate. WCP mass was lost in the thermal treatment process; with the increase in temperature, more mass losses occurred because of the water escape and chemical reaction. Figure 3 illustrates the mass change of WCP after the thermal treatment; with the increasing treatment temperature, the mass loss of WCP increased.
In Figure 4, it is obvious that the free calcium oxide content increased with the increase in temperature; especially, at 800 ℃ treatment, the value was up to 3.6%. Free calcium oxide could quickly react with water and more contents could affect the cement properties. The content of free calcium oxide in Portland linker was not more than 1.5% according to Chinese standard GB/T 21372 [24].
In Figure 5, it was measured that the powder particle size was influenced by the temperature; it decreased with the thermal treatment of 700 ℃, while it increased for 600 ℃. With the thermal treatments of 700 ℃ and 600 ℃, the size of the 90% volume (D90) was 3.08 and 17.85 μm, respectively. This was affected by the structural transformation of C-S-H, the specific surface area, and the pore volume of cement paste by 600 ℃ treatment, which was the biggest compared to those by heat treatment under 1000 ℃ [21].
3.2. Change of Activity Materials in WCP by the Thermal Treatment
Although cement paste probably contained unhydrated clinker, it was not determined in samples of this study. WCP mainly comprises cement paste and concrete aggregate powder. Calcium carbonate is an inert material, and therefore, the WCP property is determined by the activity of cement paste. New active materials could be produced in WCP by the thermal treatment [25]. New larnite and calcium silicates (Ca3SiO5 and Ca2SiO4) were measured in the WCP at 800 ℃ by XRD experiment, and they are active materials and can react with water (Figure 6).
The SEM figures illustrated the particle characteristics of the WCPs without thermal treatment and with 600 ℃, 700 ℃, and 800 ℃ treatments (Figure 7).
Compared to unheated WCP, big cluster structures like arborization in WCP were formed by 600 ℃ treatment. After 700 ℃ treatment, small clusters could be observed, and the size of WCP heated by 800 ℃ was bigger than that of WCP heated by 700 ℃ but smaller than that of WCP heated by 600 ℃. These results were consistent with the size change described in Figure 5. Unlike those of the WCPs heated by 600 ℃ and without thermal treatment, the surfaces of WCPs heated by 700 and 800 ℃ had many holes, and those changes were probably caused by the dehydration and recrystallization of C-S-H [26] and the decomposition of calcium carbonate.
3.3. Application of WCP in Mortar with the Replacement of Cement
If WCP is used in concrete as an admixture, the mechanical strength of mortar must adhere to the regulations of the standard, which means that the activity index must overrun 65% of values of reference mortar according to the standard requirement in Table 3.
The mechanical strength of mortars is listed in Table 4. Using Equation 1, AI was calculated and is shown in Table 5. By reference to the Chinese standard (Table 3), AI values except those treated at 700 ℃ could not attain the requirement for the active mineral admixture used in concrete. The AI value of mortar with WCP heated by 700 ℃ could meet the class Ⅱ requirement, which meant WCP heated by 700 ℃ could be regarded as an admixture for mortar or concrete. The mortar with WCP heated by 600 ℃ had the smallest AI value. The active larnite and Ca3SiO5 were gauged in WCP heated by 800 ℃ by XRD; however, the AI of mortar with WCP heated by 800 ℃ did not obviously exceed the value of 65%.
4. Discussion
Property changes of WCP with thermal treatment and the use of WCP-replaced cement in concrete were studied in this study. Finer WCP particles at 700 ℃, as well as new active materials β-C2S and Ca3SiO5 in WCP heated by 800 ℃, were detected. Activity indexes (AIs) of WCPs by testing and calculating the mechanical strength were carried out. The finer WCPs with 700 ℃ thermal treatment achieved an optimum AI.
The mortar with thermally treated WCP by 700 °C treatment exhibited better mechanical performance because of its smaller particle size, which meant a better packing due to the filler effect, where it was proved by Berodier et al. that the presence of “inert” fillers could induce shearing in the mixing, which was recognized to affect hydration. Smaller particles could enhance the shearing, generate more nucleation sites on the cement surface, and increase the hydration acceleration rate [27].
WCP treated by 700 ℃ treatment can be reused as an admixture in concrete by the 30% replacement of cement, which can meaningfully realize up-cycling for concrete waste.
5. Conclusions
WCP was heated by 200 ℃, 400 ℃, 600 ℃, 700 ℃, and 800 ℃ and added in mortar, replacing 30% cement. Some properties of WCP and the mechanical strength of Mortar were determined. The following conclusions were obtained.
- (1)
- The particle size of waste concrete powder changed after heat treatments of 200 ℃, 400 ℃, 600 ℃, 700 ℃, and 800 ℃; the treatment of 700 ℃ decreased the particle size of WCP; and its D90 size was reduced by 55% with comparison to the original WCP.
- (2)
- More mass loss and free calcium oxide generation in WCP occurred after the heat treatment in 800 ℃; furthermore, some active materials in WCP treated at 800 ℃ were determined by XRD detection.
- (3)
- The activity index (AI), which was measured by the ratio of mechanical strengths between the mortar with 30% replacement of cement by WCP to those of the original mortar, demonstrated that the WCP treated at 700 ℃ could be used in concrete as an admixture.
Author Contributions
Conceptualization and writing—original draft preparation, Y.S.; data curation, C.O., S.L. and J.Z.; writing—review and editing, Q.T. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by the Shandong province key R&D program (Public Welfare) 2019, Grant number 2019GSF109108, the scientific research foundation for the returned overseas Chinese scholars, State Education Ministry, grant number: (2013)1792 and the fund project of collaborative Innovation Center of green building of Shandong Province.
Acknowledgments
The authors would like to thank S.S. Liu for his contribution of SEM images detection.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
Waste concrete powder (WCP) particle distribution.
Figure 2.
Heat flow change of WCP with differential scanning calorimetry (DSC) detection.
Figure 3.
WCP mass losses with the thermal treatment.
Figure 4.
Free calcium oxide content in WCP.
Figure 5.
WCP particle analysis: (a) Accumulated particle size; (b) the particle size of 90% volume (D90).
Figure 5.
WCP particle analysis: (a) Accumulated particle size; (b) the particle size of 90% volume (D90).
Figure 6.
Mineral compositions in WCP determined by XRD.
Figure 7.
SEM detection for the microstructure with 20,000 times. (a) Original WCP, (b) WCP heated by 600 ℃, (c) WCP heated by 700 ℃, and (d) WCP heated by 800 ℃.
Figure 7.
SEM detection for the microstructure with 20,000 times. (a) Original WCP, (b) WCP heated by 600 ℃, (c) WCP heated by 700 ℃, and (d) WCP heated by 800 ℃.
Table 1.
Chemical ingredients of waste concrete powder (WCP) and cement used in the measure (%).
| CaO | SiO2 | Al2O3 | Fe2O3 | MgO | K2O | Na2O | SO3 | P2O5 | Loss | |
|---|---|---|---|---|---|---|---|---|---|---|
| WCP | 56.75 | 20.50 | 8.42 | 3.99 | 3.84 | 1.08 | 0.49 | 3.49 | 0.13 | 1.04 |
| Cement | 58.14 | 20.65 | 8.62 | 3.13 | 3.33 | 0.63 | 0.21 | 3.95 | 0.18 | 1.16 |
Table 2.
Recipe of the experiment according to Chinese Standard GB/T 17671.
| Samples | Cement | WCP | Standard Sand | Water | W/C | |||||
|---|---|---|---|---|---|---|---|---|---|---|
| g | g | g | g | / | ||||||
| Thermal Treatment (℃) | ||||||||||
| 0 | 200 | 400 | 600 | 700 | 800 | |||||
| E-0 | 450 | 1350 | 225 | 0.5 | ||||||
| E-1 | 315 | 135 | ||||||||
| E-2 | 135 | |||||||||
| E-3 | 135 | |||||||||
| E-4 | 135 | |||||||||
| E-5 | 135 | |||||||||
| E-6 | 135 | |||||||||
Table 3.
Requirement of activity index (AI) values of compound mineral admixtures for concrete according to Chinese standard JG/T486-2015 [13].
Table 3.
Requirement of activity index (AI) values of compound mineral admixtures for concrete according to Chinese standard JG/T486-2015 [13].
| Day | Activity of Compound Mineral Admixtures for Concrete | |||
|---|---|---|---|---|
| Class Ⅰ | Class Ⅱ | Class Ⅲ | ||
| AI (%) | 7 | ≥80 | ≥70 | ≥65 |
| 28 | ≥90 | ≥75 | ≥70 | |
Table 4.
Mechanical strengths of mortars with the heated WCP for replacing 30% cement.
| Day | Reference Mortar | Replacement 30% | ||||||
|---|---|---|---|---|---|---|---|---|
| 0 ℃ | 200 ℃ | 400 ℃ | 600 ℃ | 700 ℃ | 800 ℃ | |||
| Flexible strength (MPa) | 3 | 5.44 | 3.58 | 3.33 | 3.66 | 3.81 | 4.91 | 3.96 |
| 7 | 7.27 | 4.43 | 5.72 | 6.52 | 5.15 | 6.42 | 5.36 | |
| 28 | 8.79 | 4.63 | 6.18 | 7.06 | 5.89 | 6.83 | 6.23 | |
| Compressive strength (MPa) | 3 | 29.41 | 17.68 | 14.34 | 14.97 | 16.68 | 23.71 | 17.53 |
| 7 | 46.82 | 25.16 | 26.20 | 29.92 | 23.16 | 33.43 | 28.44 | |
| 28 | 55.34 | 41.91 | 38.98 | 42.64 | 39.82 | 47.71 | 36.98 | |
Table 5.
AI values for heated WCP according to the mechanical strengths.
| Day | Reference Mortar | Replacement 30% | ||||||
|---|---|---|---|---|---|---|---|---|
| 0 ℃ | 200 ℃ | 400 ℃ | 600 ℃ | 700 ℃ | 800 ℃ | |||
| AI of flexible strength (%) | 3 | 100 | 65.8 | 61.2 | 67.3 | 70.0 | 90.0 | 72.8 |
| 7 | 100 | 60.9 | 78.7 | 89.7 | 70.8 | 88.3 | 73.7 | |
| 28 | 100 | 52.7 | 70.3 | 80.3 | 67.0 | 77.7 | 70.9 | |
| AI of compressive strength (%) | 3 | 100 | 60.1 | 48.8 | 50.9 | 56.7 | 80.6 | 59.6 |
| 7 | 100 | 53.7 | 56.0 | 63.9 | 49.5 | 71.4 | 60.7 | |
| 28 | 100 | 75.7 | 70.4 | 73.5 | 72.0 | 86.2 | 66.8 | |
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Sui, Y.; Ou, C.; Liu, S.; Zhang, J.; Tian, Q. Study on Properties of Waste Concrete Powder by Thermal Treatment and Application in Mortar. Appl. Sci. 2020, 10, 998. https://0-doi-org.brum.beds.ac.uk/10.3390/app10030998
AMA Style
Sui Y, Ou C, Liu S, Zhang J, Tian Q. Study on Properties of Waste Concrete Powder by Thermal Treatment and Application in Mortar. Applied Sciences. 2020; 10(3):998. https://0-doi-org.brum.beds.ac.uk/10.3390/app10030998
Chicago/Turabian StyleSui, Yuwu, Chuping Ou, Shu Liu, Jinshuai Zhang, and Qingbo Tian. 2020. "Study on Properties of Waste Concrete Powder by Thermal Treatment and Application in Mortar" Applied Sciences 10, no. 3: 998. https://0-doi-org.brum.beds.ac.uk/10.3390/app10030998
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