To encounter the issues of waste materials, low tensile strength of concrete and environmental impacts of cement production, research is needed to develop a sustainable concrete. This study has endeavored to investigate the effects of using recycled coarse aggregates (RCA), various types of wastewater effluents, fly ash, and glass fibers on the mechanical and durability behavior of recycled aggregate concrete (RAC) incorporating with fly ash and glass fibers (FGRAC). Six different kinds of wastewater effluents for the mixing of concrete, 100% replacing the natural coarse aggregates with RCA, and 30% replacement of cement with fly ash were used for the development of concrete. The experimental measurement portrayed that the textile factory effluent presented the highest compressive and tensile strengths of concrete. Fertilizer factory effluent portrayed the highest water absorption, mass loss due to acid attack, and chloride penetration to concrete.
Para enfrentar los problemas de los materiales de desecho, la baja resistencia a la tracción del hormigón y los impactos ambientales de la producción de cemento, se necesita investigación para desarrollar un hormigón sostenible. Este estudio investiga los efectos del uso de áridos gruesos reciclados (RCA), varios tipos de efluentes de aguas residuales, cenizas volantes y fibras de vidrio sobre el comportamiento mecánico y la durabilidad del hormigón con árido reciclado (RAC), incorporando cenizas volantes y fibras de vidrio (FGRAC). Para el desarrollo del hormigón se utilizaron seis tipos diferentes de efluentes de aguas residuales, se sustituyó el 100% de los áridos gruesos naturales por RCA y el 30% del cemento por cenizas volantes. Se comprobó que el empleo de efluente de fábrica textil promovió la mayor resistencia a la compresión y a la tracción del hormigón. El empleo del efluente de la fábrica de fertilizantes presentó la mayor absorción de agua, pérdida de masa debido al ataque de ácido y penetración de cloruro en el hormigón.
The construction industry is generating a large quantity of construction and demolishing waste in the form of concrete waste which needs to be properly managed for sustainable development. The application of concrete waste in the form of recycled aggregate concrete (RAC) minimizes the requirement of landfills for the demolition waste, and transportation costs of aggregates by preserving the natural resources, reclamation lands, and reducing the number of loads headed to landfills (
It was concluded that RAC-produced concrete exhibits inferior characteristics as compared to traditional concrete (
After examining the behavior of concrete fabricated with cementitious wash water, Asadollahfardi et al. (
Many studies explore the performance of RAC with fly ash (
The contaminated wastewater is producing negative impacts on the natural atmosphere as well as on human health. Therefore, such adverse impacts on the environment and human health could be avoided up to a certain limit by using wastewater in the concrete mix. Furthermore, to overwhelm the low tensile strength of plain concrete and the high carbon footprint of the cement industry, the use of glass fibers and fly ash to concrete is beneficial. In this study, mechanical properties such as compressive strength and split tensile strength as well as durability properties i.e., water absorption, chloride penetration, and resistance against H_{2}SO_{4} of the recycled aggregate concrete incorporating with fly ash and glass fibers (FGRAC) have been studied under different curing ages by employing six types of wastewater for mixing purpose such as domestic sewage wastewater (DSW), fertilizer factory wastewater (FFW), textile factory wastewater (TFW), sugar factory wastewater (SFW), leather factory wastewater (LFW), and service station wastewater (SSW). One concrete mix was manufactured with potable water without adding glass fibers and fly ash for the comparative analysis. A one-way variance analysis (ANOVA) study was conducted at the five percent significance level to determine the value of discrepancy between the different properties of FGRAC mixes.
Ordinary Portland cement having grade 43 was employed for concrete production as per ASTM C150/C150M (
Physical properties | Chemical properties | ||||
---|---|---|---|---|---|
Parameter | Cement | Fly ash | Component | Cement | Fly ash |
Consistency (%) ( |
29.2 | 28.6 | SiO_{2} (%) | 22.3 | 60.4 |
Specific gravity ( |
3.0 | 2.3 | Al_{2}O_{3} (%) | 5.7 | 26.7 |
Final setting time (mins) ( |
235 | - | SO_{3} (%) | 2.5 | 1.1 |
Initial setting time (mins) ( |
110 | - | MgO (%) | 5.3 | 0.8 |
Specific surface area (m^{2}/kg) ( |
330 | 423 | CaO (%) | 59 | 4.2 |
Fineness (Blaine Test) (cm^{2}/g) | 2770 | 2950 | Fe_{2}O_{3} (%) | 6.0 | 2.5 |
Compressive strength at 3 days (MPa) ( |
38.5 | - | Loss of ignition (%) | 2.9 | 4.2 |
Compressive strength at 28-days (MPa) ( |
42.5 | - | K_{2}O (%) | 0.8 | - |
Soundness ( |
No expansion | - | Na_{2}O | 0.4% | 1.4 |
Property | Sand | RCA |
---|---|---|
Water absorption after one day (%) | 2.25 | 7.7 |
Fineness modulus | 2.45 | - |
Specific gravity | 2.62 | 2.25 |
Dry density (kg/m^{3}) | 1650 | 1305 |
Maximum size (mm) | 4.75 | 12.0 |
Minimum size (mm) | - | 4.75 |
Parameter | Value | Parameter | Value |
---|---|---|---|
Diameter ( | 15 | Length (mm) | 8-16 |
Melting point (^{o}C) | 1000 | Texture (g/km) | 80 |
Loss on ignition at 900^{o}C (%) | 1.15 | Moisture (%) | 0.4 |
Elastic modulus (GPa) | 70 | Tensile strength (MPa) | 1800 |
Specific gravity | 2.65 | Density (kg/m^{3}) | 890 |
Parameter (unit) | PW | FFW | TFW | SSW | DSW | SFW | LFW |
---|---|---|---|---|---|---|---|
pH value | 7.0 | 2.5 | 7.2 | 6.0 | 7.4 | 7.5 | 6.5 |
TDS (mg/l) | 761.6 | 2138 | 325.6 | 416.5 | 931.6 | 2712.2 | 387 |
TSS (mg/l) | 26.4 | 47.6 | 18.7 | 59.5 | 433.5 | 58.7 | 35.2 |
Turbidity (NTU) | 0.8 | 2.8 | 1.0 | 31.5 | 212.5 | 21.3 | 22.6 |
DO (mg/l) | 5.4 | 2 | 4.5 | 2.2 | 2.4 | 2.6 | 5.3 |
COD (mg/l) | 15.8 | 488.3 | 102 | 1207 | 357.9 | 807.5 | 1075 |
BOD (mg/l) | 10.4 | 518.5 | 59.5 | 952 | 264.4 | 612 | 852 |
Alkalinity (mg/l) | 69.8 | 1.4 | 40.8 | 73.1 | 82.5 | 104.6 | 23.5 |
Conductivity (m-s/cm) | 1.2 | 7.3 | 0.6 | 0.7 | 1.6 | 5.7 | 1.4 |
Bicarbonates (mg/l) | 283.1 | 180 | 10.8 | 297.5 | 340 | 637.5 | 14.3 |
Hardness (mg/l) | 307.7 | 2176 | 290.7 | 314.5 | 612.9 | 1802 | 225.4 |
Sulphate (mg/l) | 6.2 | 807.5 | 89.3 | 98.6 | 641.8 | 178.5 | 74.6 |
Fluoride (mg/l) | 0.3 | 0.1 | 0.6 | 0.1 | 1 | 0.4 | 0.5 |
Nitrate (mg/l) | 1.2 | 56.1 | 2.4 | 8.5 | 86.7 | 27.2 | 2.2 |
Chloride (mg/l) | 10.4 | 892.5 | 53.9 | 212.5 | 289 | 732.7 | 183.4 |
Iron (mg/l) | 1.7 | 3.1 | 0.8 | 1.0 | 0.7 | 1.3 | 1.2 |
To achieve an optimal saturation, the RCA was submerged in potable water for 10 minutes (
A total of twenty-one cylindrical specimens (150 mm 300 mm) from each wastewater (constant quantity) were prepared for the determination of compressive strength and splitting tensile strength. Three samples for each wastewater at all ages were prepared and tested. A total of forty-two specimens (50 mm height and 100 mm in diameter) were developed for examining the waster absorption. For the determination of chloride ion migration, forty-two samples (100 mm in diameter and 100 mm in height) were also prepared. Whereas, sixty-three cube samples of size 100 mm were cast to explore the resistance of FGRAC concrete against sulfuric acid attack. The ingredients and quantities utilized for each FGRAC blend as shown in
Mix ID | Mixing water | Cement (kg/m^{3}) | Fly ash (kg/m^{3}) | Glass fibers (kg/m^{3}) | RCA (kg/m^{3}) | Sand (kg/m^{3}) | |
---|---|---|---|---|---|---|---|
Type | Content (kg/m^{3}) | ||||||
PW30-GF-100RCA | Potable water | 233 | 466 | 94 | 12 | 1050 | 625 |
DS30-GF-100RCA | Domestic sewage | 233 | 372 | 94 | 12 | 1050 | 625 |
FF30-GF-100RCA | Fertilizer factory | 233 | 372 | 94 | 12 | 1050 | 625 |
TF30-GF-100RCA | Textile factory | 233 | 372 | 94 | 12 | 1050 | 625 |
SF30-GF-100RCA | Sugar factory | 233 | 372 | 94 | 12 | 1050 | 625 |
SS30-GF-100RCA | Service station | 233 | 372 | 94 | 12 | 1050 | 625 |
LF30-GF-100RCA | leather factory | 233 | 372 | 94 | 12 | 1050 | 625 |
A mixer at a speed of 20 revolutions/min (capacity of 0.15 m^{3}) was used to mix concrete. A total of 10 minutes required for complete mixing. To achieve a homogenous mixture, the aggregate was mixed with water, fly ash, and cement in the first 5 minutes then added the remaining quantity of water and the glass fibers. For each wastewater mix, a slump test (as per ASTM/C143) was performed and its values ranging between 90 mm to 105 mm (
The properties such as compressive strength and split tensile strength for each RAC blend at different curing ages were tested. The compressive strength of specimens at 7, 28, and 90-days was tested according to ASTM C39 (
To find out how chloride ion penetrates, the specimens developed have been cured in water for 28 and 90-days, preceded by oven-drying at a temperature of 50°C for 24 hours. Following this, the specimens were cooled to normal temperature and then submerged in a solution of 4% NaCl for 56 days. The splitting of cylinders procedure was followed as per the ASTM C496 (
In this current investigation, the compressive strength for each of the six different FGRAC mixes was tested after 7, 28, and 90-days of curing as per ASTM C39 (
The compressive strength of concrete for the TF30-GF-100RCA mix improved dramatically when compared with PW30-GF-100RCA at all ages. At 7-days, the TF30-GF-100RCA blend showed a compressive strength of 22.4 MPa which was 17.6% higher as compared to the compressive strength of PW30-GF-100RCA at 7-days. After 28-days, the compressive strength of the TF30-GF-100RCA mix was increased by 135% having a value of 34.6 MPa which was 24.8% higher as compared to the compressive strength of the PW30-GF-100RCA mix. When bicarbonates and fluoride existing in TFW involves a reaction with Al_{2}O_{3} remaining in ordinary Portland cement and thus proceed to calcium fluoroaluminate formation leading to the increased compressive strength of concrete. This mineral is extremely toxic, resulting in both fast setting and early hydration, which improved the performance (
The improved compressive strengths of FGRAC mixes developed with wastewater could be ascribed to the pozzolanic reactions between free fly ash and CH. Fly ash filled the voids between sand and cement, improved the bond of glass fibers with the binding matrix, and, finally, formed a gel (C-S-H-gel) giving a stronger bond. Furthermore, the ability of glass fibers to prevent the propagation of cracks also improved the compressive strength of FGRAC mixes to give comparable results with the control mix.
By using FFW to produce FGRAC mixes, the compressive strength attained at 7-days was higher and lesser at 28 and 90-days associated with PW30-GF-100RCA. At 7-days, the FF30-GF-100RCA mix exhibited a compressive strength of 21.2 MPa that is 13% higher than the compressive strength of PW30-GF-100RCA at 7-days. The compressive strength of the FF30-GF-100RCA mix was increased by 15.6% at 28-days having a value of 25.2 MPa. It was further decreased by 7.8% at 90-days when compared with PW30-GF-100RCA but it showed 12.9% higher strength than at 28-days. This drop in the compressive strength of FF30-GF-100RCA mix at 28 and 90-days of testing occurred because of an increased quantity of COD as well as BOD at 5-days in FFW (
When DSW has been used for mixing, the compressive strength of concrete decreased considerably. At 7-day testing, the compressive strength was observed 11.9 MPa, at 28-days testing it was 18 MPa, and at 90-day testing, it was 15.3 MPa. The average compressive strengths were 35%, 30%, and 51% lower than the strengths reported in the same order by the PW30-GF-100RCA mix at testing days of 7, 28, and 90. The uniformity of the mixing water has a significant effect on concrete strength. Consequently, the concrete strength for DS30-GF-100RCA is lower than PW30-GF-100RCA. While at 28-days of testing, this strength of the DS30-GF-100RCA mix increased to 34.3% and it shows a reduction of up to 15% at testing days of 90. This reduction in the strength of the DS30-GF-100RCA mix can be due to the existence of many organic matters in DSW that reacts with cement ingredients and thus result in reducing the strength of concrete. Due to the large amount of sulfate found in DSW, the compressive strength of the DS30-GF-100RCA mix is decreased after 90-days of testing.
When SSW was used for mixing, then the compression capacity of concrete was affected to a slight extent. It had shown compressive strengths of 16.9 MPa in 7-days, 23.9 MPa in 28-days, and 29.8 MPa in 90 test days. These compressive strengths were in similar accordance with that of the PW30-GF-100RCA mix and on average 8.4%, 8%, and 4.8% were lower than compressive strengths displayed by the PW30-GF-100RCA mix at the testing days of 7, 28, and 90. These negligible variations indicate that the concrete compressive strength has no noticeable effect when SSW is used for mixing. The reason is that SS30-GF-100RCA has shown a decline in strength at all test ages which can be due to the existence of BOD and COD in excessive amounts. The concrete compressive strength decreased at 7-days by using SFW comparison to the PW30-GF-100RCA mix, which subsequently increased to 43.9% after 28-day testing. SF30-GF-100RCA mix has shown increased strength because of the long setting time of cement paste and the larger surface area of cement particles (
When LFW was used for mixing, then the compression capacity of concrete was affected to a slight extent. It had shown compressive strengths of 16.7 MPa in 7-days, 29.9 MPa in 28-days, and 30.5 MPa in 90 test days. These compressive strengths were in similar accordance with that of the PW30-GF-100RCA mix and on average 9.5%, 3.3%, and 7% lower than compressive strengths displayed by the PW30-GF-100RCA mix at the testing days of 7, 28, and 90. These negligible variations indicate that the concrete compressive strength has no noticeable effect when LFW is used for mixing. The reason is that LF30-GF-100RCA has shown a decline in strength at all test ages that may be associated with a large amount of COD and BOD in LFW. The improved compressive strengths of FGRAC mixes fabricated with wastewater could be ascribed to the pozzolanic reactions between free CH and fly ash. Fly ash filled the voids between sand and cement, improved the bond of glass fibers with the binding matrix, and, finally, formed a gel (CSH-gel) giving a stronger bond. Furthermore, the ability of glass fibers to prevent the propagation of cracks also improved the compressive strength of FGRAC mixes to give comparable results with the control mix.
The FF30-GF-100RCA mix indicated split tensile strengths of 2.36 MPa at 7-days, 2.68 MPa at 28-days, and 3.17 MPa at 90-days, respectively. This indicates that the split tensile strengths were reduced by 3.6% at 7-days, by 5.9% at 28-days, and by 8.4% at 90-days associated with the control mix when FFW was used for mixing. The tensile strengths demonstrated by the DS30-GF-100RCA mix were small with falls of 8.9% at 7-days, 7% at 28-days, and 9.8% at 90-days as compared with the PW30-GF-100RCA mix. The SF30-GF-100RCA mix displayed split tensile strengths of 2.34 MPa at 7-days, 2.71 MPa at 28-days, and 3.29 MPa at 90-days with a reduction of 4.5% at 7-days, 5.0% at 28-days, and 4.8% at 90-days, respectively. The decreases in split tensile strengths displayed by diverse FGRAC mixes (i.e. FF30-GF-100RCA, DS30-GF-100RCA, SS30-GF-100RCA, and SF30-GF-100RCA) can be due to the excess of total suspended solids, COD, and BOD in such kinds of wastewater (
Being a durability parameter, the water absorption calculates the number of pores that are moisture-accessible in concrete. If water absorption is extreme, it will cause reinforcement corrosion which leads to the penetration of numerous toxic chemicals and when react with cement additives thus completely change the characteristics of concrete.
Different FGRAC mixes reported a reduction in the properties of water absorption with time. The water absorption shown by the PW30-GF-100RCA mix was 12.5% at 28-days and 9.2% at 90-days, representing the decline in moisture content over time. As compared to PW30-GF-100RCA, the water absorption shown by the TF30-GF-100RCA mix was lower. The moisture content was 99% at 28-days and 98% at 90-days equated to PW30-GF-100RCA. The decline in water absorption may be attributed to a reduction in the amount of chloride, as the volume of chloride rises, the concrete density lessens with reduced strengths plus enhanced porosity in concrete (
When tested at 28 and 90-days, correspondingly, the water absorption values of the FF30-GF-100RCA mix were 9.7% and 16.5% higher than that of PW30-GF-100RCA. The DS30-GF-100RCA mix displayed moisture content that is the highest with 14.6% at 28-days, 12% at 90-days that have been 14.7%, and 23.9% higher than with the PW30-GF-100RCA mix. The large quantities of organic wastewater existing in DSW contribute to the establishment of large numbers of small pores resulting in higher water absorption. The water is consumed by such waste during the mixing process and then emitted during concrete casting, which increases the ratio of water to cement (W/C) and thus decreases the concrete density (
In this study, chloride penetration of concrete is studied using 4% NaCl. The method used to calculate this parameter is the penetration of ions color in millimeters penetrated by the chloride ions into the concrete microstructure.
The control mix portrayed a chloride penetration of 11.87 mm at 28-days, and 7.45 mm at 90-days. At 28 and 90-days, the TF30-GF-100RCA mix displayed chloride penetration that was 12.6% higher and 18.9% higher than PW30-GF-100RCA. This depicts the TF30-GF-100RCA mix as more vulnerable to oxidation and steel bar corrosion. Also, penetration of chloride indicated by the FF30-GF-100RCA blend was 14.23 mm in 28-days and 10.41 mm in 90-days. Chloride ion penetration is also enhanced by the pretty low pH value of FFW (
Fewer iron quantities in the DSW resulted in the chloride penetration values being close to the control mix. The chloride penetration shown by the SS30-GF-100RCA blend was 13.37 mm and 9 mm at 28- and 90-days, which is 11.2% and 17.2% higher on average than PW30-GF-100RCA values. The SF30-GF-100RCA mix demonstrated chloride penetration values close to those of the SS30-GF-100RCA mix. Similarly, the LF30-GF-100RCA mix depicted higher values of chloride ion penetration (12.24 mm at 28-days and 9.64 mm at 28-days) that were 3% and 22.7% higher than the control mix at 28 and 90-days, respectively. Hence, the chloride ion penetration represented by DSW was the lowest from all forms of wastewater tested, which indicates that it is less prone to corrosion.
This study examined the mass loss of test samples at 28, 90, and 120-days after soaking them in 4% of the H_{2}SO_{4} solution.
The degradation of the TF30-GF-100RCA mix is quicker than the control mix. TF30-GF-100RCA mix reported mass losses of 6.28% after 28-days, 13.11% after 90-days, and 16% after 120-days, which were 30.2%, 23.3%, and 15.8% higher than the PW30-GF-100RCA mix. The FF30-GF-100RCA mix reported mass losses of 7.3% at 28-days, 14.89% at 90-days, and 17.86% at 120-days that were 40%, 32.5%, and 24.5% higher than the PW30-GF-100RCA mix. The largest mass loss of the FF30-GF-100RCA mix can be linked to the lowest pH value (
Groups | Counts | Sum | Average | Variance | ||
---|---|---|---|---|---|---|
PW30-GF-100RCA | 3 | 78.1500 | 26.0500 | 66.560643 | ||
DS30-GF-100RCA | 3 | 54.1462 | 18.0487 | 67.912354 | ||
FF30-GF-100RCA | 3 | 75.4650 | 25.1550 | 36.207506 | ||
TF30-GF-100RCA | 3 | 103.927 | 34.6425 | 128.911553 | ||
SF30-GF-100RCA | 3 | 82.0050 | 27.3350 | 72.507675 | ||
SS30-GF-100RCA | 3 | 71.83125 | 23.94375 | 24.922110 | ||
LF30-GF-100RCA | 3 | 75.5950 | 25.198333 | 0.3862583 | ||
ANOVA | ||||||
Source of Variation | SS (Sum of squares) | DOF (Degrees of freedom) | MS (Mean squares) | F | P-value | F_{crit} |
Between Groups | 434.72027 | 6 | 72.4533799 | 1.2762036 | 0.3290271 | 2.8477259 |
Within Groups | 794.81621 | 14 | 56.7725864 | |||
Total | 1229.5364 | 20 |
Groups | Counts | Sum | Average | Variance | ||
---|---|---|---|---|---|---|
PW30-GF-100RCA | 3 | 8.535 | 2.845 | 1.6319437 | ||
DS30-GF-100RCA | 3 | 7.957 | 2.652 | 1.3675687 | ||
FF30-GF-100RCA | 3 | 8.040 | 2.680 | 0.973425 | ||
TF30-GF-100RCA | 3 | 10.810 | 3.603 | 1.6917520 | ||
SF30-GF-100RCA | 3 | 8.122 | 2.707 | 1.7310937 | ||
SS30-GF-100RCA | 3 | 8.017 | 2.672 | 1.0766437 | ||
LF30-GF-100RCA | 3 | 9.045 | 3.015 | 1.6688250 | ||
ANOVA | ||||||
Source of Variation | SS (Sum of squares) | DOF (Degrees of freedom) | MS (Mean squares) | F | P-value | F_{crit} |
Between Groups | 2.12158214 | 6 | 0.3535970 | 0.24407037 | 0.95387880 | 2.84772599 |
Within Groups | 20.2825041 | 14 | 1.4487502 | |||
Total | 22.4040863 | 20 |
Groups | Counts | Sum | Average | Variance | ||
---|---|---|---|---|---|---|
PW30-GF-100RCA | 3 | 27.585 | 9.195 | 0.863325 | ||
DS30-GF-100RCA | 3 | 36.277 | 12.092 | 2.143481 | ||
FF30-GF-100RCA | 3 | 33.075 | 11.025 | 4.648275 | ||
TF30-GF-100RCA | 3 | 28.5675 | 9.5225 | 3.911643 | ||
SF30-GF-100RCA | 3 | 33.2775 | 11.092 | 0.343743 | ||
SS30-GF-100RCA | 3 | 35.7675 | 11.922 | 0.168882 | ||
LF30-GF-100RCA | 3 | 31.2775 | 10.425 | 2.892077 | ||
ANOVA | ||||||
Source of Variation | SS (Sum of squares) | DOF (Degrees of freedom) | MS (Mean squares) | F | P-value | F_{crit} |
Between Groups | 22.199291 | 6 | 3.69988184 | 1.7299067 | 0.18648402 | 2.84772599 |
Within Groups | 29.942854 | 14 | 2.138775298 | |||
Total | 52.142145 | 20 |
Groups | Counts | Sum | Average | Variance | ||
---|---|---|---|---|---|---|
PW30-GF-100RCA | 3 | 22.3545 | 7.4515 | 2.05862475 | ||
DS30-GF-100RCA | 3 | 23.6145 | 7.8715 | 2.26391025 | ||
FF30-GF-100RCA | 3 | 31.2396 | 10.4132 | 2.67804012 | ||
TF30-GF-100RCA | 3 | 27.5709 | 9.1903 | 8.68046907 | ||
SF30-GF-100RCA | 3 | 27.9069 | 9.3023 | 3.35724627 | ||
SS30-GF-100RCA | 3 | 26.9871 | 8.9957 | 0.81108867 | ||
LF30-GF-100RCA | 3 | 28.9069 | 9.6356 | 4.636279603 | ||
PW30-GF-100RCA | 3 | 22.3545 | 7.4515 | 2.05862475 | ||
ANOVA | ||||||
Source of Variation | SS (Sum of squares) | DOF (Degrees of freedom) | MS (Mean squares) | F | P-value | F_{crit} |
Between Groups | 18.592055 | 6 | 3.0986758 | 0.88585449 | 0.53040232 | 2.84772599 |
Within Groups | 48.971317 | 14 | 3.4979512 | |||
Total | 67.563372 | 20 |
Groups | Counts | Sum | Average | Variance | ||
---|---|---|---|---|---|---|
PW30-GF-100RCA | 3 | 30.1428 | 10.0476 | 3.12473535 | ||
DS30-GF-100RCA | 3 | 29.3265 | 9.7755 | 4.90601475 | ||
FF30-GF-100RCA | 3 | 44.6775 | 14.8925 | 10.05263175 | ||
TF30-GF-100RCA | 3 | 39.3277 | 13.1092 | 5.591521688 | ||
SF30-GF-100RCA | 3 | 36.1961 | 12.0653 | 7.141446047 | ||
SS30-GF-100RCA | 3 | 39.1807 | 13.0602 | 8.130450563 | ||
LF30-GF-100RCA | 3 | 33.1961 | 11.0653 | 6.490071047 | ||
ANOVA | ||||||
Source of Variation | SS (Sum of squares) | DOF (Degrees of freedom) | MS (Mean squares) | F | P-value | F_{crit} |
Between Groups | 61.0771561 | 6 | 10.179526 | 1.56825679 | 0.22813058 | 2.84772599 |
Within Groups | 90.8737424 | 14 | 6.4909816 | |||
Total | 151.950898 | 20 |
The findings of the ANOVA test indicate that different FGRAC mixes did not show a substantial difference at 28-days of testing (
The statistical analysis of the durability and mechanical properties of FGRAC mixes portrayed that the compressive and tensile strengths are not influenced by using different types of wastewater examined in the present work. Similarly, no significant differences in the durability properties of FGRAC mixes (water absorption, chloride penetration, and concrete mass loss due to acid attack) were observed. This statistical analysis shows that the examined types of wastewater can be employed for the mixing of concrete without meaningly affecting the mechanical and durability behavior of concrete.
The present study investigates the mechanical and durability behavior of recycled aggregate concrete incorporating with fly ash and glass fibers (FGRAC) manufactured using different categories of wastewater. One concrete mix was fabricated with potable water without adding glass fibers and fly ash for the comparative analysis. A one-way ANOVA test was carried out to study the significance of using different wastewater types, fly ash, and glass fibers on the mechanical and durability behavior of FGRAC mixes. Key points of the present study are reported below.
FGRAC mix made with textile factory wastewater represented the maximum compressive strength of 37.7 MPa at 90-days that was 16.8% higher than the control mix. The addition of fly ash and glass fibers improved the compressive strength of FGRAC mixes by forming a CSH-gel and providing a bridging effect between the binder matrices. Correspondingly, the compressive strengths of FGRAC mixes made with FFW, SSW, SFW, and LFW were 7.8%, 4.8%, 7.7%, and 7% lower than the control mix.
The highest split tensile strength was portrayed by the FGRAC mix made with textile factory wastewater with a value of 4.1 MPa at 90-days that was 15.6% higher than the control mix. Correspondingly, the split tensile strengths of FGRAC mixed manufactured with FFW, SSW, SFW, and LFW were 8.3%, 3.4%, 4.9%, and 2% lower than the tensile strength of the control mix.
The FGRAC mix fabricated with domestic sewage wastewater presented the highest water absorption at 28-days that was 23.9% higher than the water absorption of the control FGRAC mix.
The chloride penetration test portrayed that all the FGRAC mixes presented higher values of chloride ion penetrations than the control mix. Fly ash reduced the chloride penetration by forming a stronger CSH bond, but the addition of glass fibers increased the voids to enhance the chloride penetration.
The attack of FGRAC mixes to 4% solution of H_{2}SO_{4} reported that all the mixes presented higher values of mass loss as compared with the control mix. The addition of glass fibers caused an enhancement in the air voids increasing mass loss. The FGRAC mix made with fertilizer factory effluent portrayed the highest value of mass loss of concrete that was 32.5% higher than that of the control mix at 120-days.
The statistical study of the testing measurements indicated no significant difference between the various mechanical and durability performance of FGRAC mixes made with different types of effluents.
Finally, it can be concluded that all types of wastewater examined in the present study can be employed for manufacturing the concrete without significantly disturbing the mechanical and durability behavior of concrete directing towards sustainable development by overcoming the carbon footprint and low tensile strength of concrete
Conceptualization: A. Raza, B. Ali. Data curation: F.U. Haq, M. Awais, M.S. Jameel. Formal analysis: A. Raza, M. Awais Investigation: A. Raza, B. Ali, M. Awais. Methodology: A. Raza, F.U. Haq. Resources: F.U. Haq, M. Awais, M.S. Jameel. Software: A. Raza, B. Ali. Validation: B. Ali, F.U. Haq, M.S. Jameel. Visualization: M. Awais. Roles/Writing, original draft: A. Raza. Writing, review & editing: B. Ali, M. Awais, M.S. Jameel.