Cement
Cements are products that, when mixed with water, set and harden, forming new compounds resulting from hydration reactions that are stable both in air and submerged in water.[32].
There are several types of cements. The properties of each of them are closely associated with the chemical composition of their initial components, which is expressed in the form of their oxides, and depending on which ones they are, they will form different resulting compounds in the hydration reactions.[32].
Each type of cement is indicated for certain uses; Environmental conditions also determine the type and class of cement, affecting the durability of concrete. The types and names of cements and their components are standardized and subject to strict conditions. The Spanish standard establishes the following types: common cements, those resistant to sulfates, those resistant to seawater, those with low heat of hydration, white cements, those for special uses and those made of calcium aluminate. Common cements are the most important group and among them Portland is the usual one. In Spain, only cements legally marketed in the European Union can be used and are subject to the provisions of specific laws.[33].
In addition to the type of cement, the second factor that determines the quality of the cement is its class or 28-day compressive strength. This is determined in a standardized mortar and expresses the minimum resistance, which must always be exceeded in the manufacture of cement. It is not the same, nor should the resistance of cement be confused with that of concrete, since that of cement corresponds to standardized components and that of concrete will depend on each and every one of its components. But if the concrete is well dosed, the greater the resistance of the cement, the greater the resistance of the concrete.[32] The Spanish standard establishes the following resistance classes:[33].
Cement is in powder form and the fineness of its grinding is decisive in its binding properties, decisively influencing the speed of the chemical reactions of its setting and first hardening. When mixed with water, the cement grains are hydrated only to a depth of 0.01 mm, so if the grains were very thick, the hydration performance would be small as an inert core would remain inside. However, excessive fineness causes high shrinkage and heat of hydration. Furthermore, since resistance increases with fineness, a compromise solution must be reached; the cement must be finely ground, but not excessively.[32].
The storage of bulk cement is carried out in sealed silos that do not allow contamination of the cement and must be protected from humidity. For cements supplied in bags, storage must be carried out in covered, ventilated premises, protected from rain and sun.[33] Prolonged storage can cause the hydration of the finer particles due to weathering, losing their hydraulic value and resulting in a delay in setting and a decrease in resistance.[34].
Portland cement is obtained by calcining artificially prepared mixtures of limestone and clay at about 1500 °C. The resulting product, called clinker, is ground by adding an appropriate amount of setting regulator, which is usually natural gypsum stone.[35].
The average chemical composition of a portland, according to Calleja, is made up of 62.5% CaO (combined lime), 21% SiO (silica), 6.5% AlO (alumina), 2.5% FeO (iron) and other minorities. These four components are the main ones of cement, lime is basic and the other three are acidic. These components are not free in the cement, but combined forming silicates, aluminates and calcium ferrites, which are its hydraulic components or potential components. A medium type Portland cement clinker contains:[35].
The two main hydration reactions that cause the setting and hardening process are:
Tricalcium silicate is the active compound par excellence of cement as it develops a high initial strength and a high heat of hydration. It sets slowly and hardens quite quickly. In fast-hardening and high-resistance cements it appears in a higher proportion than usual.[35].
Dicalcium silicate is what develops long-term resistance in cement, it is slow in setting and hardening. Its chemical stability is greater than that of tricalcium silicate, which is why sulfate-resistant cements have a high content of dicalcium silicate.[35].
Tricalcium aluminate is the compound that governs setting and short-term strength. Its chemical stability is good against seawater, but very weak against sulfates. In order to stop the rapid reaction of tricalcium aluminate with water and regulate the setting time of the cement, gypsum stone is added to the clinker.[35].
Tetracalcium aluminatoferrite") does not participate in the mechanical resistance, its presence is necessary due to the contribution of iron fluxes in the manufacture of clinker.[35].
In Spain there are so-called "Portland cements with active additions" that, in addition to the main components of clinker and gypsum stone, contain one of these additional components up to 35% of the weight of the cement: steel slag "Slag (metallurgy)"), silica fume, natural pozzolana, calcined natural pozzolana, siliceous fly ash, calcareous fly ash, calcined shale or limestone.[33].
High initial strength cements, those resistant to sulfates, those with low heat of hydration or white ones are usually special Portland cements and for them some of the four basic components of clinker are limited or enhanced.[36].
Steel cement is obtained by joint grinding of Portland clinker and setting regulator in a proportion of 5-64% with steel slag in a proportion of 36-95%.[33] It constitutes the family of cold cements. Slag is obtained by suddenly cooling the molten gangue from steelmaking processes in water; In this cooling the slag vitrifies and becomes hydraulically active due to its combined lime content. The slag on its own sets and hardens slowly, so Portland clinker is added to accelerate it.[36].
Pozzolanic cement is a mixture of Portland clinker and setting regulator in a proportion of 45-89% with pozzolana in a proportion of 11-55%.[33] Natural pozzolana has volcanic origin and although it does not have binding properties, it contains silica and alumina capable of fixing lime in the presence of water, forming compounds with hydraulic properties. Artificial pozzolana has analogous properties and is found in fly ash, diatomaceous earth or active clays.[36].
Aluminous cement is obtained by melting limestone and bauxite. The main constituent of this cement is monocalcium aluminate.[36].
Arid
Aggregates must have at least the same resistance and durability required for concrete. Soft limestone, feldspars, gypsum, pyrites or friable or porous rocks should not be used. For durability in aggressive environments, siliceous aggregates, those from the crushing of volcanic rocks or healthy, dense limestones, will be better.[37].
The aggregate that has the greatest responsibility in the whole is sand. According to Jiménez Montoya, it is not possible to make good concrete without good sand. The best sands are river sands, which are normally pure quartz, which ensures their resistance and durability.[37].
With natural rolled aggregates, the concrete is more workable and requires less mixing water than crushed aggregates, also having the guarantee that they are hard and clean stones. Crushed aggregates from crushing, having more fracture faces, cost more to put into use, but they lock better and this is reflected in greater resistance.[37].
If the rolled aggregates are contaminated or mixed with clay, it is essential to wash them to remove the jacket that surrounds the grains and that would reduce their adhesion to the concrete paste. Likewise, crushing aggregates are usually surrounded by crushing dust, which increases the fines in the concrete, requires more mixing water and will give lower resistance, which is why they are usually washed.[37].
The aggregates used in concrete are obtained by mixing three or four groups of different sizes to achieve an optimal granulometry. Three factors intervene in an adequate granulometry: the maximum size of the aggregate, the compactness and the content of fine grains. The larger the maximum size of the aggregate, the lower the cement and water needs will be, but the maximum size is limited by the minimum dimensions of the element to be built or by the separation between reinforcement, since these gaps must be filled by concrete and, therefore, by larger aggregates. In a mixture of aggregates, a high compactness is one that leaves few voids; It is achieved with mixtures low in sand and a large proportion of coarse aggregates, requiring little mixing water; Its great difficulty is to compact the concrete, but if sufficient means are available to do so, the result is very resistant concrete. Regarding the content of fine grains, these make the mixture more workable but require more mixing water and cement. In each case a compromise formula must be found taking into account the different factors. The Fuller and Bolomey parabolas give two families of granulometric curves widely used to obtain adequate dosages of aggregates.[37].
Water
The mixing water intervenes in the hydration reactions of the cement. The amount must be strictly necessary, since the excess that does not intervene in the hydration of the cement will evaporate and create voids in the concrete, reducing its resistance. It can be estimated that each liter of excess mixing water means canceling two kilos of cement in the mixture. However, an excessive reduction of water would cause a dry mixture, unwieldy and very difficult to place on site. Therefore, it is very important to properly set the amount of water.[38].
The characteristics of water for concrete must be evaluated so that it does not produce adverse reactions in the mixture, which is why physical-chemical analyzes must be carried out to guarantee its quality. In practice, a simple indicator is the potability of the water, with this we can determine if the water is suitable for use in the mixture or not.
During the setting and first hardening of the concrete, curing water is added to prevent desiccation and improve the hydration of the cement.[38].
Both the water intended for kneading and that intended for curing must be suitable to fulfill their function. It is very important that the curing water be suitable as it can more negatively affect the chemical reactions when the concrete is hardening. Normally, suitable water usually coincides with drinking water and a series of parameters that must be met are standardized. Thus, the regulations limit the pH, the content of sulfates, chlorine ion and carbohydrates.[38].
When a mass is excessively fluid or very dry, there is a danger of the segregation phenomenon occurring (separation of concrete into its components: aggregates, cement and water). It usually occurs when concrete is poured with material drops greater than 2 meters.[28].
Other minority components
The basic components of concrete are cement, water and aggregates; Other minor components that can be incorporated are: additions, additives, fibers, fillers and pigments.
Additives and additions can be used as components of concrete, provided that through the appropriate tests, it is justified that the added substance in the proportions and conditions provided produces the desired effect without excessively disturbing the remaining characteristics of the concrete or representing a danger to the durability of the concrete or to the corrosion of the reinforcement.[39].
Additions are inorganic, pozzolanic or latent hydraulic materials that, finely ground, can be added to concrete at the time of its manufacture, in order to improve some of its properties or give it special properties. The EHE only includes the use of fly ash and silica fume, determining its limitations. It is composed of limestone crushed into very small pieces like powder, and other materials such as HQR chemicals (herqiros) among others.
Additives are substances or products that are incorporated into concrete, before or during mixing, producing the modification of some of its characteristics, its usual properties or its behavior. The EHE establishes a proportion of no more than 5% of the weight of the cement and other conditions.