Influence of selected activating methods on hydration processes of mixtures containing high and very high amount of fly ash

Wilińska, Iwona; Pacewska, Barbara

doi:10.1007/s10973-017-6915-y

Cited by 58 publications

(41 citation statements)

References 107 publications

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“…Fly ash has been utilized as supplementary cementitious material for decades. Different amounts of this by-product in cement composite can be considered: up to 35 mass% (typical amount), about 50% (high volume fly ash concretes (HVFAC) [1][2][3][4][5]) or even 70-80% (very HVFAC [6][7][8][9][10]). Moreover, there is also possibility of using fly ash as binding material performed without cement (alkali activated fly ash, geopolymers) [11][12][13][14][15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

“…This binding material is composed of high amount of fly ash (at least 70 mass%) and Portland cement. Moreover, it is activated with alkaline media; thus, it can be considered as hybrid cement [7,8,10,[35][36][37][38][39][40]. It is important that in the case of hybrid cements, alkalinity may increase in situ as a result of chemical reaction, e.g., using Na 2 SO 4 as an activator [5,7,38,39].…”

Section: Introductionmentioning

confidence: 99%

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Comparative investigation of reactivity of different kinds of fly ash in alkaline media

Wilińska

Pacewska

2019

J Therm Anal Calorim

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Comparison of the influence of temperature and different alkali activators on the reactivity of two types of fly ash (conventional, fluidized) was presented. The main emphasis was put on fluidized fly ash as potential component of binding mixtures containing low amount of cement. Conventional fly ash was used as a reference. It was found that for these materials the key differences affecting products of activation are: availability of calcium and sulfate ions as well as structure of fly ash grains influencing dissolution of aluminate and silicate species. Fluidized fly ash, contrary to conventional fly ash, undergoes reaction in 0.1 M solutions of hydroxides forming mainly ettringite. In the case of 4 M hydroxides, both fly ashes undergo hydration processes. Conventional fly ash formed mainly amorphous aluminosilicate gel, while fluidized fly ash may create zeolitic products especially in the case of elevated temperature of early hydration. Sulfate and alkali ions can be incorporated into aluminosilicate structure of new formed products; however, this process depends strictly on the type of used hydroxide and its concentration. The presence of Ca(OH) 2 , carbonates and alkali sulfates was also registered in the case of hydrated fluidized fly ash.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Comparative investigation of reactivity of different kinds of fly ash in alkaline media

Wilińska

Pacewska

2019

J Therm Anal Calorim

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“…Therefore, obtaining hardened material with the required properties requires investigation and analysis of the physicochemical processes occurring over time in the system. In some cases, the starting material may require an additional treatment and modification procedure (e.g., chemical or physical activation) [4][5][6][7], and the composition of the mix should be optimized. It is also important that the final material does not adversely affect its user, so it is necessary to study, e.g., its natural radioactivity.…”

Section: Introductionmentioning

confidence: 99%

Holistic Analysis of Waste Copper Slag Based Concrete by Means of EIPI Method

et al. 2019

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The aim of the research is a comprehensive evaluation of concrete using the EIPI method. In the evaluation the compressive strength of concrete and its durability properties represented by sorptivity and air permeability are taken into account. Since waste copper slag with increased natural radioactivity is used in the assessed concrete, additional evaluation is carried out taking into account the influence of natural radioactivity within the performance index. Additionally, the reference concrete, which is made without the use of waste copper slag, is evaluated for comparative purposes. In order to make the evaluation as comprehensive as possible, the concrete made with the use of three types of cement is subjected to CEM I, CEM II and CEM III assessments. If natural radioactivity is not taken into account in the evaluation, the best result of the most favourable value of Gross Ecological and Performance Indicator (GEPI) is obtained by the concrete made with waste copper slag, and if radioactivity is considered, the most favourable value of GEPI is obtained with concrete without addition of the waste. The results show that in both approaches the best result is achieved by concrete with CEM III cement. It follows from the above that although natural radioactivity has a significant impact on the EIPI evaluation result, the decisive factor is still the type of cement.

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“…Many researches on concrete are aiming to create more advantageous concrete from strength and durability standpoint with the application of innovative admixtures and supplementary cementitious materials (SCMs) [1]. SCMs are highly advantageous, because besides their positive effects on strength and durability, they have environmental benefits, like the reduction in carbon dioxide emission and decreasing the porosity of normal-strength concrete [2][3][4][5][6]. The strict European air pollution regulations have produced many industrial by-products that can be used as supplementary cementitious materials, like metakaolin (MK) or silica fume.…”

Section: Introductionmentioning

confidence: 99%

Cellular concrete waste as an economical alternative to traditional supplementary cementitious materials

Gyurkó

Szijártó

Nemes

2019

J Therm Anal Calorim

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Traditional supplementary cementitious materials (SCMs), like metakaolin or microsilica, highly improve various properties of concrete, making it more resistant against the effects of the environment. However, the cost of concrete is highly influenced by the applied amount of SCMs. Cellular concrete powder (CCP) is a by-product, produced by the cutting and curving process of cellular concrete blocks, which has the possibility to be used for similar purposes as SCMs. The present paper introduces the results of the laboratory experiments, conducted by the authors, and their analysis. The experiments were designed to investigate the effects of CCP on mortars, normal and high-strength concretes in terms of strength and durability. To get a deeper understanding of the processes taking place in a mortar or concrete containing CCP, thermogravimetric analysis was performed as well. CCP was applied in the mixes in different amount, and the performance of CCP was compared to SCMs. CCP was found to be a feasible alternative to SCMs in case of normal-strength concrete, while in case of high-strength concrete it did not improve the strength of the reference concrete. It could be traced back to the sulfate swelling of CCP particles. In optimal dosage, CCP was found to be preferable to metakaolin (MK) for durability characteristics. The combined usage of CCP and MK was investigated as well, but it did not result a concrete with better performance than the reference mix.

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Influence of selected activating methods on hydration processes of mixtures containing high and very high amount of fly ash

Cited by 58 publications

References 107 publications

Comparative investigation of reactivity of different kinds of fly ash in alkaline media

Comparative investigation of reactivity of different kinds of fly ash in alkaline media

Holistic Analysis of Waste Copper Slag Based Concrete by Means of EIPI Method

Cellular concrete waste as an economical alternative to traditional supplementary cementitious materials

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