1. Introduction
Addition of fly ash and kaolin to concrete offers advantages such as performance improvement, reduction of the amount of by-product materials, landfill cost and enables manufacturers to minimize mining and processing virgin materials, thereby reducing the emission of carbon dioxide.
Four basic ingredients of the conventional concrete are Portland cement, fine and coarse aggregates and water. The production of high performance concrete (HPC) needs to incorporate the supplementary cementations materials such as fly ash and kaolin in the concrete mix [1] . Low calcium fly ash (ASTM Class F) and kaolin have been widely used as a replacement of cement in normal and high strength concrete [2] [3] .
In normal strength concrete, the replacement level of fly ash can be more than 50% [4] [5] , while in high strength concrete, the replacement level is usually limited to 15% ± 25% [2] . The main objectives of using fly ash in high strength concrete are to reduce heat generation and to obtain better durability properties. For several cases, early strength of concrete was low, particularly where a significant portion, 30 percent or more, of the Portland cement was replaced with fly ash [6] . Wild et al., [7] proved that for addition of metakaolin up to 30%, compressive strength at 28 days increased within the range of 1.53% - 35%. However, Priyank, et al., found that the compressive strength decreased when replacement with kaolin percentage increased. The fact is that the type of kaolin affects the concrete strength [8] .
The property of concrete which determines the amount of useful internal work necessary to produce full compaction is known as workability. The workability of fresh concrete depends mainly on the material, mix proportion and environmental conditions. The use of pozzolan, such as fly ash, plays an important role in contributing to a better workability of HPC [9] . Tanaka et al. [10] found that with 10% lesser water binder ratio, the workability of the concrete increased with an increase in amount of fly ash. Wild et al. found that workability of concrete at 0.45 water cement (w/c) decreased with increase in replacement of cement by metakaolin.
In the present study, the effect of fly ash and kaolin on concrete strength and workability were studied, and a comparison of the two binders was made.
2. Experimental Work
2.1. Materials
Kaolin materials from North Omdurman, Khartoum State and class F fly ash study sample from Road and Building Institute, University of Khartoum with the following compositions were used for the experimental work Table 1.
2.2. Experimental Method
2.2.1. Concrete Mix with Fly Ash and Kaolin
Concrete mixtures and cement paste was prepared with (8.75 kg cement,18.75 kg fine aggregate, 28.13 kg coarse aggregate and 5.28 kg water ) in a ratio of (1:2:3). Fly ash was used in the proportions of 10%, 20%, and 30 wt% of the total cementitious materials. The concrete mixtures were proportioned and mixed in a pan mixer, Photo 1 . For concrete kaolin mixture, the kaolin to cement replacement ratio was 10%, 20%, and 30 wt%.
Table 1. Fly ash and kaolin chemical composition.
Photo 1. Pan mixer.
2.2.2. Comprehensive Strength
Compaction of fresh concrete in 6 cubic steel moulds was achieved, applying Thirty-five manual strokes per layer in three equal layers. The cube dimension was 150 mm × 150 mm × 150 mm. For comprehensive strength the cubes were left to dry for one day and then immersed in water, three of the cubes were left for 7 days and the other three were left for 28, the compressive strength was measured in N/mm2, using compressive testing machine Photo 2 .
2.2.3. Workability Test
The slump test used to characterize the workability of concrete. Its apparatus consists of a mold in the shape of a frustum of a cone with a base diameter of 8 inches, a top diameter of 4 inches, and a height of 12 inches, Photo 3 . The mold was filled with concrete in three layers of equal volume. Each layer was compacted with 25 strokes of a tamping rod. The slump cone mold was lifted vertically upward and the change in height of the concrete was measured.
Photo 2. Comprehensive strength machine.
Photo 3. Slump cone mold.
3. Results and Discussion
The comprehensive strength for 7 days and 28 days, and the workability of concrete with fly ash and kaolin with 10%, 20%, 30% were measured. The results were shown in Figures 1-4.
For the sample where the strength was measured after 7 days, the comprehensive strength of concrete was reduced with the addition of fly ash, the strength was reduced by 10%, 21.2%, 40.8% with the addition of 10%, 20%, 30% respectively. For the long term immeresion, 28 days, the strength increased by 4.99% with 10% fly ash, then the strength was reduced by 14% and 27.5% with 20%, 30% fly ash addition. The fact that for long term process the pozzolana materials in Flass F fly ash, react with water and cement for higher concrete strength. The best result was obtained with 10% fly ash.
Fly ash samples under study consist low CaO of 1.12%. The reason that at early strength age (7 days) of 10% fly ash replacement to cement, the calcuim, alumunum, silicon constitutes react with water to form pozzolan complex polymer that enhance the strength of concrete mix. With increasing the replacement ratio of fly ash to
Figure 1. Concrete strength with fly ash.
Figure 2. Concrete workability with fly ash.
Figure 3. Concrete strength with kaolin.
Figure 4. Concrete workability with kaolin.
cement, the calcium content was reduced and concrete strength as well. For kaolin samples there are no calcuim, so the 100% concrete pose highest strength.
Since Class F ash reacts slowly with water. The complete pozolana reactions will complete after long time, the strength of concrete cubes were high after 28 days. The results was agreed with other researcher that concerte class F fly ash have slow strength gain at early ages and delayed setting that results in extended curing time requirements [11] .
The concrete workability which represents the mixture ability to fill the mold properly with the desired work, without reducing the concrete’s quality, was increased with the addition of fly ash. The maximum workability was achieved at 30% fly ash.
For concrete-kaolin mixture the strength was reduced to 40.8% of the ummix concrete with the addition of 30% kaolin in 7 days. For the 28 days the strength reduction percent is 44.7 % with 30% kaolin replacement.
Dramatic reduction in concrete workability was obtained with the increasing kaolin amount. With 30% kaolin the workability was approximately zero.
In general, small particle size of kaolin and fly ash with higher specific surface area are favorable to produce highly dense and impermeable concrete; however, they cause lower concrete workability.
4. Conclusions
The following conclusions are drawn on the use of fly ash and kaolin in concrete making:
1) The addition of fly ash for long life term improves the concrete strength.
2) Addition of 10% fly ash increases the concrete strength.
3) Higher fly ash cement replacement in concrete reduces the comprehensive strength.
4) The concrete workability is improved with fly ash addition.
5) The addition of Kaolin under study reduces the comprehensive strength and workability.
6) The fly ash improves the concrete properties better than kaolin. The fact is that the calcium and aluminum content in fly ash are higher than that in kaolin, which enhances the pozzolana reactions when the water is added to the fly ash concrete mix.
Acknowledgements
Authors are thankful to the Road and Building Research Institute, University of Khartoum―Sudan, for their great help during the experimental programme.