Patent Application
20160343460
The present invention relates to a mass preparation for the manufacture of structural technical concretes, either in mass or prefabricate, specially designed for the realisation of radiation shields, whether refractory resistant to high temperature or not, and/or for thermal accumulation, usable in the making of supporting structures for radiological spaces or shields for waste containers, that allows the construction of radiological or nuclear containments with adequate security and efficiency. It also relates to a method for obtaining said preparation.
The invention falls generally in the field of building materials.
Currently, the protection of premises, facilities and waste against the action of radiation requires the use of high density concretes (greater than 3000 Kg/m3), and typically barite concrete, that are capable of attenuating the irradiated particles, that have a high cost and have mechanical strength characteristics similar to those of other concretes like the same type PORTLAND cement, and are capable of better controlling the possible occurrence of micro-cracks in large masses of concrete, due to a better control over curing temperatures.
In general, refractory concretes have the drawback of the appearance of cracks or micro-cracks when subjected to high temperatures. These cracks, even though they do not seriously affect the structural capacity of the material, cause a loss of thermal conductivity due to the breakage of the corresponding thermal bridges, impairing its characteristics of accumulation and manageability of thermal energy, and to a lesser extent the shield.
As a consequence of this, these concretes are being used in most cases merely as structures resistant to high temperatures, and primarily as prefabricated elements for the containment of spaces at high temperatures. Attempts have been made to control this situation by treating the aggregate and the use of additives, arriving at the increase of the mechanical characteristics of the concrete as well as increasing the thermal conductivity and thermal capacity, but without being applied to concretes with capabilities for shielding against radiation.
Therefore, in the state of the art, the lack of refractory shield concretes is evident that, apart from maintaining adequate structural capacities, are able to provide for a high capacity thermal performance, high thermal and electrical conductivity, maintaining appropriate mechanical characteristics, which makes them ideal for the construction of foundations and/or radiologically safety structures.
The mass preparation for the manufacture of technical concretes for radiation shields of the invention has a constitution that overcomes the technical problem posed, obtaining a finished concrete with high capacity shielding against gamma particles and neutrons, similar to barite concrete or even higher, depending on the selection, implementation and radiological activity, but at a lower cost, and even improving certain mechanical and/or thermal properties such as:
The finished concrete made from the mass preparation of the invention, therefore, presents considerable improvements from the point of view of the structural and deformational safety, and thermal shielding of, for example, radiological waste containers, being able to be optimised to the temperature ranges in which they will be applied, for example 280° C., for shielding radioactive waste containers, or any other application at environmental temperature. It also gives a technological outlet to a metallurgy residue.
Other applications of the concrete made from the mass preparation of the invention comprise the realisation of enclosures for radioactive and similar premises, as poured concrete, bricks, tiles, or dry mortar.
The mass preparation for making technical concretes for radiation shields is of the type comprising a mixture of cement, aggregate and water. According to the invention, the cement comprises aluminous cement (with calcium aluminate base) and/or Portland type, while the aggregates comprise principally and usually only, slag from metallurgy foundry castings, and typically selected black slag.
Furthermore, it may comprise additives that vary depending on the characteristics required, such as strength, curing time, protection against freezing and others. It may also comprise the addition of a filler or filling complementary to the aggregates, which provides mechanical strength and, in particular, increases density.
Mainly the Portland type cement is used, although a variant based on aluminous cements can also be made, to create temperature resistant shields, for applications such as the manufacture of containers for radioactive waste—whether for transport or for storage—as well as other applications in which the radioactive element must be adequately confined in a high temperature environment.
The use of smelter slag as a technological aggregate brings great advantages over other natural aggregates, allowing the emergence of a new group of technical concretes optimised for the range of tasks in which must be developed their application and functionality of the same.
The preparation is achieved by the method of the invention, which comprises the following steps:
if it was a fine aggregate and is given by the equation
where y the percentage is by weight of the aggregate passing through each sieve, d is the opening of each sieve, D is the maximum aggregate size and a is a variable parameter depending on the type of aggregate and concrete consistency.
Furthermore, additives may be added depending on the characteristics that are required and/or a filler or filling in order to increase the mechanical strength and, in particular, the density.
The mass preparation for making technical concretes for radiation shields of the invention is of the type comprising a mixture of cement, aggregate and water. According to the invention, the cement comprises aluminous cement (with calcium aluminate base) and/or Portland type, while the aggregates comprise principally and usually only, slag from metallurgy foundry castings, and typically selected black slag.
Furthermore, it may comprise generally additives to provide strength, protection against freezing, accelerate curing and others. It may also comprise generally the addition of a complementary filler or filling to the aggregates to increase the mechanical strength and/or density.
Within the general scope of the invention, at least the following main variants are provided:
A mass preparation for refractory radiation shielding concrete intended to be used with functional temperatures higher than 250° C., intended for the manufacture of prefabricated parts comprising, by volume of the preparation:
A mass preparation for refractory radiation shielding concrete intended to be used in mass pouring for finished structures with functional temperatures higher than 250° C., comprising, by volume of the preparation:
Expressing the amount of aluminous cement in units used in the technical field of application, it would range from 350-450 Kg/m3 of total heavy mass, and the ratio by weight water/cement comprised between 0.28% and 0.40%.
These concretes are suitable for work at high temperatures, as their thermal expansions up to 400° C. are compatible with the dilatations experienced by carbon steel pipes that often traverse the elements made of concrete. Furthermore, if the structure requires, a carbon steel framework of not more than 12 mm can be used. If the frameworks are “skin” this should not exceed 10 mm. Stainless steel pipes in the thermal range up to 600° C. may be lined with dense steel wool and pressed to a maximum thickness of 2 mm, to maintain thermal and mechanical contact.
Portland cement cannot be used at high temperatures, as it dehydrates and begins to lose its mechanical properties at temperatures above 250° C., but if the concrete is not to be subjected to these high temperatures, Portland type cement should be used.
Therefore, the invention also contemplates main variants of the mass preparation, which are not intended to work at temperatures requiring refractory properties, and that are made with Portland cement, comprising:
A mass preparation for non-refractory radiation shielding concrete intended to be used with functional environmental temperatures, intended for the manufacture of prefabricated parts comprising, by volume of the preparation:
A mass preparation for refractory radiation shielding concrete intended to be used in mass pouring for finished structures with functional environmental temperatures, comprising, by volume of the preparation:
Expressing the amount of Portland cement in units used in the technical field of application, it would range from 290-380 Kg/m3 of total heavy mass and the ratio by weight water/cement would be comprised between 0.3% and 0.55%.
In any variant the preferred granulometry for the mix seeking the greatest radio-protection capacity would be between 0 mm and 22 mm for the manufacture, and the Bolomey curve upper limit plotted should never exceed 25 mm, due to the risk of segregation in the vibration process.
For projected mortars, the preferred granulometry of the mix would be between 0 mm and 2 mm, with maximum aggregate size of 1.3 mm.
Regarding the additives, it is provided that to any of these variants may be added, in addition to the additives generally seen, other additives such as super-plasticizers, self compactants, air entraining agents, water reducers (e.g. derivatives of polyethylene glycol, vinyl, or the like), which act as deflocculants for this type of cements. Other additives may be metal fibre, plastic or polymer fibres, curing inhibitors, etc. as recommended by the respective manufacturers based on the final design of the fabricate and the onsite laying conditions, in proportions of less than 1%. Typically, preparations based on Portland cement will use super plasticizer additives, and those preparations based on aluminous cements will use plasticizing additives and curing inhibitors. As far as additives based on plastic fibres such as polypropylene fibres are concerned, they generally improve the mechanical properties, and also in high temperature uses, generate outlet channels for subsequent humidities.
Also these variants in particular may comprise a filling or filler based on aggregates such as minerals with high iron content, for example magnetite and/or hematite and/or iron shot of very fine granule size (comprised between 60-120 μm) in maximum ratio of 10% by volume of the mixture, in order to increase the mechanical strength and, in particular, the density to within the ratios indicated in the claims of the present invention. This ratio will be substitute for the ratio of aggregates, in such a way that the inclusion of a certain percentage by volume of filler will involve the decrease of the same percentage of aggregate in the previous ratios.
Additionally these variants may in particular include nano-particles (between 60 ηm and the 400 ηm) composed of oxides and metal alloys consisting mostly of Fe, Mg and Zn, with traces of Si, Ni, S, K, Ca, and Cr, different forms of crystallization, in a proportion of less than 3% by volume of the mixture. It gives compaction, increase of the mechanical properties, impermeability, and better adhesion when used as mortar, workability and an improvement in the ability to shield. Except that, if it is required to improve any of the aforementioned parameters, in which case different fractions would have to be tried depending on the granulometric curve of the main aggregate, and the “weight” of each parameter on the list of the minimums required. The optimum on average to obtain a balanced improvement, is the use of this material at 1% by volume of the mixture. It is necessary to be cautious and prudent in the addition of nano-particles addition since it will require more water, and therefore, greater super-plasticizer which increase the heat generation and the possible emergence of micro-cracks although it gains in workability.
Below a few tables are shown that express in a concrete way the amounts of the various components, in the units in which they are normally expressed in the industry and in the various regulations, therefore, some of the amounts are indicated as percentage by volume and others as percentage by weight.
Concrete in range of environmental temperatures for prefabricates
Concrete in range of environmental temperatures for mass pourings
Concrete with refractory characteristics for prefabricates
Concrete with refractory characteristics for mass pourings
(*) Super-plasticizing additives, self compactants, air entraining agents, metallic fibre, plastic or polymer fibres, curing inhibitors, etc. as recommended by the respective manufacturers based on the final design of the fabricate and the onsite laying conditions.
The preparation is achieved by the method of the invention, which comprises the following steps:
Furthermore, additives may be added depending on the characteristics that are required and/or a filler or filling in a maximum proportion of 10% by volume in order to increase the mechanical strength and, in particular, the density.
The vibration is performed in maximum pulses of 5-10 seconds depending on the size of the aggregate (a larger aggregate less vibration time) (it must be implemented in short pulses to avoid segregation of the coarse aggregate).
The analysis of the composition and granulometry of the slags is performed by spectrophotometry X ray, or other method that gives similar information, in order to obtain a profile of components that allows to discern whether the casting, which are usually around 20 TM depending on the type of oven, is suitable for some applications in the nuclear field.
classification according to their granulometry is performed according to the following criteria:
The selection of the aggregate so that it contains at least 39% by weight of FeO and less than 4% MgO, is needed to achieve adequate shielding and thermal accumulation characteristics: the finished concrete should be heavy and with good mechanical stability. The MgO content is directly related to the volumetric stability. A too high content of Magnesium (MgO) as Periclase jeopardizes the stability. These crystals react with water and in the medium and long term, can cause internal stresses in the hardened concrete. Furthermore, it must be controlled that the CaO content is below 24% by weight to optimise the mechanical stability of the concrete.
With respect to compactness, porosity and degree of crystallinity of the granules, they are parameters that depend on the slag cooling method. If the slag is poured directly onto the floor of the mill and then watered with water to proceed to its cooling, it will have a porous and glassy appearance. If the pouring is performed in a cinder dumper or foundry cone, cooling is slower and never watered, and once cooled and extracted a hard and crystalline compact material with low porosity can be appreciated, which is preferred for use as the main aggregate in the use of the mass preparation for nuclear shielding concretes of the invention.
In the case of making prefabricated blocks with this concrete, i.e. concrete pieces manufactured in moulds, not in mass, the dosage should be adapted so that the maximum granulometry of the aggregate in these circumstances should be between half and a third of the smallest dimension of the prefabricate, with a maximum of 25 mm. It should be noted that the productions of prefabricated modules are made, at least with vibro compression.
It has also been found that, modifying the ratio between fine and coarse aggregates, the modification of the thermal properties of the material (e.g. thermal conductivity) may be achieved to suit its use in different temperature ranges and performances, and even other properties such as electrical conductivity, aspects to be taken into account in the design of shielding waste containers.
The Bolomey grading curve is plotted for each application, and unlike those based on other theories, such as that of Fuller, it does consider the cement as if it were one more aggregate, which allows for better results. The maximum deviations indicated above regarding the determined Bolomey curves determined ensure optimum performance of the finished concrete.
Varying the proportion between the amounts of sand, medium aggregates and coarse aggregates allows modifying the properties of the resulting material to adapt its use at different temperatures, and better meet the objective of application required. Indeed, it has been found that a high percentage of fine aggregates contributes to greater compaction of the mix, and therefore a higher thermal conductivity. This advantage of compaction occurs when what is sought are concretes with high shielding ability, therefore, care must be taken so that their use does not decrease the density of the fabricate.
| Number | Date | Country | Kind |
|---|---|---|---|
| P201530713 | May 2015 | ES | national |
