DE102012105226A1 - Infrared reflective concrete product useful as paving stone, exterior facade stone, masonry block or roof tile, comprises infrared reflective nanoparticles in concrete matrix, covering layer including concrete covering layer, and core layer - Google Patents

Abstract

Infrared reflective concrete product (10) comprises infrared reflective nanoparticles (18) having a non-visible size (smaller than 150 nm) included in a matrix (16) of the concrete, a covering layer (14) including a concrete covering layer made by mixing the nanoparticles in cement slurry and applying on a previously molded core layer, which provides volume, shape and stability, and a core layer (12) including a concrete core made by an ordinary cement, aggregate or water mixture, where the infrared reflective nanoparticles are included in the matrix of the concrete covering layer. An independent claim is also included for a cement mixture for preparing the concrete product, comprising the infrared reflective nanoparticles for preparing the concrete covering layer.

Description

STATE OF THE ART

The invention relates to an infrared-reflecting concrete product.

Generic concrete or paving stones usually have a core (core concrete) and a surface layer (facing layer, top layer), which is also referred to as facing concrete. The facing layer is the visible layer of the concrete product that determines the visual appearance of a building to be created. The intent or cover layer is selected by the choice of cement usually as white or gray cement in the form, color and size of the aggregate, depending on the application, and may contain pigments for color design of the surface. Pigment size and aggregate size, color and size can be varied. The aggregate is usually chosen so that a dense grain packing is formed and the attachment layer is as water and airtight as possible. The core layer is the non-visible layer below the facing layer, which is responsible for the volume and weight of the concrete product and its stability. The core concrete is in its formulation and consistency usually coarser than the facing layer, since the core concrete in the installed state does not determine the appearance of the product and must meet only the mechanical requirements.

Due to the multiple use of concrete in the building and street architecture, there is due to increasing sunlight, undesirable heating effects, so that the microclimate is degraded within urban areas, especially in summer months. In recent years, efforts have been made to use building materials with a high infrared-reflecting content, where the so-called TSR or albedo value (total solar reflectance) and the SRI value (solar reflectivity index) are significantly higher than those of ordinary concrete. For example, the United States Government's Leadership in Energy and Environmental Design (LEED) program explicitly encourages the use of building materials that are energy-efficient, water-efficient, and climate-friendly. In this context, the development of heat-reflecting concrete is promoted emphatically.

The use of infrared-reflective pigments is for example from the DE 10 2005 061 684 A1 known for paints and cosmetics. Furthermore, the use of infrared-reflecting pigments for concrete products, for example in the US 2009 027 2297 A1 However, these infrared-reflective pigments, which can be admixed with a concrete, have a high core size and thus form a visual appearance dominating part of the facade surface. An optically uninfluenced surface design with high IR reflectivity is not possible here.

In the EP 1 817 383 B1 a dark, low thermal conductivity, low solar absorption surface element is described in which the support material is a mixture of cement, calcium sulfate or anhydride, wherein nanoparticles having dimensions smaller than 100 nm may be mixed therein. The nanoparticles can be inorganic, and consist for example of titanium dioxide, zinc oxide or metal colloids. These can have a high reflection in the infrared range.

Furthermore, from the DE 600 03 181 T2 colored nanopigments of clay with an organic dye known.

It is therefore an object of the invention to provide a concrete product which reflects infrared sunlight in whole or in part within and / or outside its matrix, and increases the solar reflectance (SRI) or the thermal emittance (TSR / albedo value) such that an excessively high Heating the concrete product can be avoided. The concrete matrix should remain optically largely unchanged, so that a desired visual appearance of the concrete product remains arbitrarily adjustable. Furthermore, it is intended to reduce disturbing visible light reflections to the eye and to preserve the natural and conventional appearance of the concrete product. The excessive portion of the IR-reflecting concrete product should remain unchanged with the base formulation, i. Cement, water, and aggregate can be produced, and both in appearance and in the construction of the core concrete and the facing layer to be maintained in order to maintain a low price of the concrete product.

DISCLOSURE OF THE INVENTION

According to the invention, the object is achieved by proposing an infrared-reflecting concrete product in which infrared-reflecting nanoparticles ( 18 ) are included in a non-visible size range less than 150 nm. Infrared-reflecting nanoparticles in a non-visible size range of less than 150 nm, preferably less than 100 nm, in particular less than 30 nm, and in particular between 5 to 10 nm are thus included in the matrix of the concrete. By adding a nanocomposite in the order of magnitude of <150 nm, in particular less than 100 nm and preferably in the size range of 5 to 10 nm, it is possible to admix infrared-reflecting particles which are not visible to the human eye. but achieve a functional change in the optical concrete properties, so that non-visible components of the sunlight are reflected in the infrared spectrum, without the overall visual impression of the concrete product is changed. Thus, it is also possible to adapt the optical appearance of the concrete product as desired, for example in shape, color and surface design, but to achieve thermally favorable reflection properties.

An essential aspect of the invention thus lies in the addition of nanoparticles, for example indium tin oxide (ITO) or aluminum oxide as a nanostructured composite in powder form with a particle shape of <150 nm, which ensures a visible transparency and thus a neutrality with respect to appearance of the cover layer , The nanoparticles may be present as powder or as part of a dispersive system, such as solid mixture, suspension or emulsion. The nanoparticles can be mixed into the cement slurry of the cover layer concrete, thus ensuring homogeneous penetration of the cover layer concrete. Such concrete products may be, in particular, roof tile or tile products for roofing, house facade covering or the like. Advantageously, such concrete products are designed thin-walled, since the nanoparticles are evenly distributed in the product volume. It is also conceivable to provide a gradual variation of the nanoparticles from a lower distribution in the interior of the volume to a higher concentration at the surface of the concrete product.

In principle, the concrete product can be produced from a cement slurry with mixed-in IR-reflecting nanoparticles. According to the invention, the concrete product comprises at least one cover layer of a cover layer concrete and a core layer of a core concrete. The matrix of the topcoat concrete includes infrared-reflective nanoparticles, and the core concrete is made of a common cement / aggregate / water mixture. In the core concrete, it is possible to dispense with the addition of nanoparticles, since the core concrete remains invisible to the observer. In principle, the concrete product can only be made of or consist of the infrared-reflecting cover layer concrete, or it can be a hollow block product that is manufactured only from the cover layer concrete. Thus, the cost of the concrete product can be kept low. Structure and structure of the core concrete may correspond to the prior art known, since in the non-visible part of a building, here the core concrete, the sunlight can not get in, so that nanocomposites must not be added. The core concrete has a homogeneous density, which is usually higher than that of the top layer and dominates the strength and stiffness of the concrete product. The attachment layer can be kept correspondingly thin in order to make the addition of relatively expensive nanoparticles in small quantities cost-effective. It is also conceivable that core layer concrete and cover layer concrete mixed with nanoparticles have the same density, so that a concrete product with homogeneous mechanical properties can be provided.

According to the invention, the cover layer concrete is produced by mixing the nanoparticles into a cement slurry and applied to an already cast core layer. The cement slurry is a viscous mixture of cement and water and forms the basis for every concrete. In the cement slurry for the facing concrete, which may be designed to be particularly air- and waterproof in accordance with the exposure to weathering, the nanoparticles can already be mixed in during the production of the cement slurry and poured onto the core layer. In this case, the thickness of the core layer can be adjusted freely. By varying the mixing in of the nanoparticles, different degrees of reflection, for example for different orientations of the concrete product compared to the course of the sun, can be achieved. By structuring the nanoparticle density within the concrete product, it is also possible, for example, to set an overall optical impression and achieve an optical preferential effect of the infrared reflection so that, for example, the reflection of the infrared waves can be adjusted at a certain angle in the direction of the sky and not in the direction of the ground. The cement slurry is mixed with sand, gravel or other rock grains and can, for example, still be treated with pure quartz sand for the improved rust protection effect of steel reinforcements or other aggregates. Furthermore, color pigments can be mixed in order to adjust the optical effect of the facing concrete.

Furthermore, according to the invention, the cover layer is designed with respect to the core layer such that the core layer essentially provides volume, shape and stability of the concrete product. This means that the core layer essentially constitutes the concrete product and only a relatively thin coating layer is applied to the surface of the core layer, which has the ecologically favorable properties. As a result, costs for the nanoparticle supply are reduced and the volume of the cover layer concrete can be significantly reduced compared to the core layer concrete. The concrete product has the same mechanical properties in terms of strength, stability and durability as a conventional concrete product without added nanoparticles, however a high solar reflection rate is achieved on its surface.

According to an advantageous further development, the nanoparticles may comprise mica, metal powder pigments and / or a metallic semiconductor compound, in particular metal oxides or metal-zinc oxides. Mica are phyllosilicates and have a smooth surface as well as a high optical reflectivity of light in the infrared range. The abovementioned materials enable a high reflectivity of the attachment layer in the infrared spectrum of the sunlight and can already provide an improved thermal reflectivity of the concrete product in small attachment layer thicknesses. Due to the small size of the nanoparticles, these are not visible to the human eye and do not influence the visual appearance when added to the matrix of the top layer concrete.

With regard to the preceding exemplary embodiment, it is particularly advantageous for the nanoparticles to comprise aluminum particles, aluminum oxide particles, titanium dioxide particles (TiO ₂ ), preferably in anatase, brookite or rutile form, indium tin oxide particles (ITO), in particular aluminum-doped tin oxide particles or zinc oxide particles or a mixture thereof. The mixture can be a combination of the aforementioned particles, for example a combination of zinc oxide particles, with aluminum particles or further combinations with two, three or more different particle types. In particular, aluminum-doped zinc oxide particles are outstandingly suitable as an admixture in the cover layer. Metal powder pigments in the form of aluminum or aluminum oxides have a very high IR reflectivity, and titanium dioxide offers, in addition to the improved IR reflection, a photocatalytic self-cleaning effect. Irradiation with sunlight may degrade organic materials on the surface. The resulting concrete surfaces remain clean and have an antimicrobial effect. For some surfaces, droplet formation can be prevented, so that no fogging of this surface remains visible with the eye. In particular, metallic semiconductor compounds can provide such photocatalytic self-cleaning effects because electron-hole pairs of photons provide free radicals to decompose organic substances. These properties can be contained in the admixed nanoparticles or added by suitable mixing ratios.

Indium Tin Oxide ITO is a semi-conductive, largely transparent material in visible light with high infrared reflectivity. He is known in particular for the construction of a heat protection coating on window glass. As an alternative to indium tin oxide, it is also possible, for example, to use SnO ₂ : F, ie tin oxide doped with fluorine, ZnO: Al, ie zinc oxide doped with aluminum or SnO ₂ : Sb with antimony-doped tin oxide. The abovementioned nanoparticles can advantageously be admixed in any desired mixing ratios to form the improved properties of the cover layer concrete. .

In an advantageous development, the cement slurry of the cover layer concrete may at least partially comprise polyurethane. It is conceivable that the cement slurry is completely formed by a polyurethane slurry, so that the cement is replaced by polyurethane. This has the advantage that the added infrared-reflecting nanoparticles without mechanical post-processing for the reflection of the IR rays accumulate on the surface and thus are present on the surface in high concentration. As a result, the reflectivity of the top layer concrete surface is significantly improved, especially when the proportion of polyurethane in the cement slurry is increased, or when polyurethane completely replaces the cement.

In an advantageous further embodiment, white or brightly reflecting additives and / or bright, light-reflecting aggregates and sands may be added to the nanoparticles and / or the cement matrix, i. be added to the cement. These additives may have a particle size <100 nm, but also have a particle size well above 100 nm, so that the overall visual impression is influenced by the additives. The aggregates and sands can be part of the cement and improve the reflection effect of the top layer concrete by their bright, reflective coloring. Due to the light color of the outer surface, in addition to the infrared-reflecting nanoparticle effect, an improved infrared reflectivity is achieved, in particular on the surface of the concrete product.

According to an advantageous development of the invention, the proportion by weight of the nanoparticles in the cover layer concrete is at least 5 to 30%, in particular 8 to 20%. By increasing the proportion by weight, the advantageous effect of the infrared-reflecting nanoparticles is generally improved. However, if the proportion of nanoparticles is too high, the overall visual impression can be changed so that a compromise can be found in the given amount. With the given mixing ratios, the overall impression of the surface design of the concrete product is retained, and by the infrared-reflective effect, a satisfactory result can be achieved.

In principle, the nanoparticles can be composed of the specified additives. In an advantageous development, a multilayer structure of the nanoparticles, in particular in a sequence of mica metal powder / semiconductor compound, can take place. Preferably, the nanoparticles are doped with aluminum or another metal, for example zinc, tin, iron, copper, tungsten or another metal, in order to bring about an improvement in the infrared-reflecting properties in the concrete matrix. Due to the multi-layered structure, in addition to the improved IR reflectivity, an increased longevity and chemical stability of the nanoparticles against external environmental influences can be achieved.

Thus, in a further advantageous embodiment, the nanoparticles may have a coating, in particular a mica-metal and / or an oxide coating, for example a coating with a transparent SiO ₂ surface. As a result, the nanoparticles are encapsulated and long-lasting chemically resistant to environmental influences. This can provide a lasting and advantageous IR reflectivity of the concrete product over decades.

In principle, the thickness of the cover layer can be arbitrary. Advantageously, the thickness may be of the order of 3 to 20 mm, in particular 5 to 10 mm. Thus, in the most bulky concrete products, the topcoat only has a small component of the thickness of the concrete product, so that increased costs for the nanoparticles are negligible with respect to the overall production costs of the concrete product. Due to the given thicknesses, a long-lasting and durable cover layer is guaranteed even in heavily used pavement or pavement surfaces with high surface abrasion and a sufficiently high density of nanoparticles can be applied to maintain the advantageous properties of the concrete product.

Furthermore, it is advantageously possible that the cover layer can be colored as desired, and the nanoparticles, regardless of the coloration, provide the necessary infrared reflection, in particular with a high concentration of the nanoparticles on the surface of the cover layer. Since the nanoparticles appear visually inconspicuous, any coloring of the cover concrete can be made in order to achieve a pleasing overall visual impression. Thus, the cover layer may be bright, dark or colored in any color, with a constant IR reflectivity can be achieved regardless of the color, and thus an adapted and individual surface appearance with high infrared reflectivity are created so that the concrete product can be used in many ways , For the coloring, the type of aggregate can be varied and various oxides, in particular metal and silicon oxides can be used.

In an advantageous embodiment, the covering layer for exposing the infrared-reflecting nanoparticles can be post-processed mechanically, in particular ground, blasted, milled or otherwise roughened. Mechanical reworking can be used to remove covering cement veils and cement layers and to clean the surface so that the IR-reflecting particles can be exposed. Also, the surface of the cover layer is smoked and enlarged, for example by water-sand or shot peening, mechanical milling, grinding, creasing. Roughening increases the effective surface area of the cover layer and exposes IR-reflecting nanoparticles so that a higher rate of reflection can be achieved.

In an advantageous embodiment, additional nanoparticles can be introduced into the surface of the cover layer prior to curing of the cover layer, in particular blown in, scattered in or applied in a different manner. Thus, an increased concentration of nanoparticles can be introduced into the surface of the cover layer prior to curing of the cover layer, and a gradual distribution of the nanoparticles with increased concentration on the surface and decreasing concentration in the direction of core concrete can be achieved so that the IR-reflecting effect on the surface becomes clear can be improved. The nanoparticles may be interspersed into the not completely cured top layer, blown or sputtered with air pressure or introduced by a vapor deposition process in the surface or adsorbed

Alternatively, in an advantageous embodiment, the cover layer may be provided with a planar nanocoating. Thus, an additional nanostructure is used up on the cover layer, which can act, for example, superhydrophobic, ie liquid repellent and liquid bead forming or superhydrophilic, ie liquid repellent and liquid film forming. The nano-coating can be sprayed on or mechanically removed on the surface, whereby common adsorption and deposition methods can be used. Thus, the topcoat surface is sealed and water repellent, whereby the surface can be easily cleaned. The nanocoating can advantageously have infrared-reflecting properties or contain infrared-reflecting nanoparticles. The coating can prevent spray paint from adhering and, if necessary, provide a lotus effect, so that greases, oils and acids are also rejected can. Furthermore, the nano-coating can improve the mechanical strength and abrasion resistance of the surface. The coating can penetrate into the aggregate and thus cause a smooth surface and a deep-penetrating seal of the concrete product.

Finally, in an advantageous embodiment, the concrete product may be designed as a paving stone, as an external facade stone, as a brick or as a roof tile. Particularly in the case of high mechanical loads, such as pavement or pavement pavement, a high longevity can be achieved by mixing the particles into the matrix of the cover layer of vis-a-vis IR-reflecting paints or a surface application of infrared-reflecting particles.

In a secondary aspect, the invention relates to a cement mixture, which can be present ready for processing, for example as ready-mixed concrete, or as cement, for example as bagged product, the cement mixture comprising infrared-reflecting nanoparticles for producing a cover layer concrete. The cement mixture is prepared ready for use according to the properties of the concrete product described above and ready for use as a cement slurry, e.g. dissolved in water for the production of a top layer of the concrete product to be used. The cement mixture is thus an essential element for the production of the infrared-reflecting concrete product and its composition determines the reflective effect of the concrete product to be produced. The cement or polyurethane blended nanoparticles may have the aforementioned properties and the mixture may contain bright, reflective additives. The cement mix provides a ready-to-use mix for the simple and cost-effective production of any concrete products that can be pre-produced as well as used directly on a construction site for customizing a concrete product.

DRAWINGS

Further advantages result from the present description of the drawing. In the drawings, embodiments of the invention are shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

Show it:

1 a paving stone of an embodiment according to the invention of a concrete product with an enlarged nanostructure of the cover layer concrete;

2 an embodiment of a piling stone according to the invention;

3 an embodiment of a capstone according to the invention;

4 an embodiment of a jacket stone according to the invention;

5 an embodiment of a brick according to the invention;

6 an embodiment of a solid casing stone according to the invention.

EMBODIMENTS OF THE INVENTION

In the figures, the same or similar components are numbered with the same reference numerals.

1 shows a paving stone 10 that's made of a core layer 12 and a cover layer 14 consists. The cover layer 14 is made of durable and abrasion-resistant concrete, which is impermeable to air and water, and of a slight thickness compared to the core layer 12 having. In the matrix 16 of the top layer concrete 12 are nanoparticles 18 mixed, the infrared reflective effect. The nanoparticles 18 have a size <150 nm and are invisible to the human eye. Due to a high proportion of nanoparticles 18 based on the total surface of the cover layer, a high infrared reflectance of the cover layer 14 be achieved. The peculiarity of the paving stone 10 is that infrared-reflective material such as indium tin oxide or similar substances in the top layer concrete mixed directly into the cement slurry and evenly distributed in nanostructured powder form for targeted reflection of sunlight-infrared radiation is included. The advantages of direct mixing are the complete penetration of the cement matrix 16 , Since the concrete surface is heavily stressed by a traffic wear in their lifetime, in particular infrared-reflecting surface coatings are unsuitable, so that the interference in the facing concrete ensures a long service life and weather resistance of the infrared-reflective effect of the paving stone. The appearance of the concrete surface remains unaffected, and the traffic load wears off the facing layer, but retains its infrared-reflective effect. Thus, the desired building biology function of the concrete product is maintained throughout its lifetime.

Since indium has a high price and is available only in small amounts, other comparable metal semiconductor products, for example tin oxide FTO, aluminum zinc oxide AZO or antimony tin oxide ATO can be used. By using inexpensive, already in the macro range used infrared-reflecting particles in nanostructured areas, a cheap economic concrete product can be provided. Aluminum-based metal pigments have increased infrared reflection within the metals. Furthermore, nanoparticles of titanium dioxide, preferably in anatase and rutile form, are very well suited for ensuring high infrared reflection capabilities of the facing layer.

In the 2 to 6 other concrete products for different applications are shown. So shows 2 a piling stone, as he can serve as a paragraph stone for a roadway or a pedestrian crossing, for example, and on two sides a cover layer 14 of infrared-reflective material around a core of core-layer concrete 12 having.

In 3 is shown a capstone, as it can be used for example as a roof crown or as a crown, and on the surface and on both side surfaces of an infrared-reflective cover layer 14 having.

4 shows a coat stone 40 For example, for the construction of a free-standing stile or stone strut fully encased with a cover layer 14 is enveloped infrared-reflective material.

5 shows a brick 50 how it can be used to build a Einziegelmauer, on both sides of the wall an infrared-reflective coating 14 wearing.

Finally shows 6 a full-coat stone 60 How it can be used universally for all types of use of a concrete product.

It is also conceivable to use a concrete product as a roof tile, which consists essentially of a core concrete, and a thin cover layer with infrared-mixed nanoparticles 18 contains, through which a roof area only slightly heated and the mass of heat can be thrown back into the atmosphere.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102005061684 A1 [0004]
• US 20090272297 A1 [0004]
• EP 1817383 B1 [0005]
• DE 60003181 T2 [0006]

Claims (16)

Infrared-reflecting concrete product ( 10 . 20 . 30 . 40 50 . 60 ) with infrared-reflecting nanoparticles included in the matrix of the concrete ( 18 ) in a non-visible size range smaller than 150 nm, characterized in that the concrete product ( 10 . 20 . 30 . 40 50 . 60 ) at least one cover layer ( 14 ) from a cover layer concrete ( 16 ) and a core layer ( 12 ) of a core concrete, wherein in the matrix of the cover layer concrete ( 16 ) the infrared-reflecting nanoparticles ( 18 ), and the core concrete is made of an ordinary cement / aggregate / water mixture, and wherein the top layer concrete ( 16 ) by mixing in the nanoparticles ( 18 ) in a Zementschlemme and on an already cast core layer ( 12 ), and the core layer ( 12 ) provides substantially volume, shape and stability of the concrete product. Concrete product according to claim 1, characterized in that the nanoparticles ( 18 ) are smaller than 100 nm, in particular smaller than 30 nm, and in particular between 5 to 10 nm in size. Concrete product according to claim 1 or 2, characterized in that the nanoparticles ( 18 ) Mica, metal powder pigments and / or a metallic semiconductor compound, in particular metal oxides or metal-zinc oxides. Concrete product according to claim 3, characterized in that the nanoparticles ( 18 ) Aluminum particles, aluminum oxide particles, titanium dioxide TiO ₂ particles, preferably in anatase, brookite or rutile form, indium tin oxide ITO particles, in particular aluminum-doped tin oxide particles or zinc oxide particles or a mixture thereof. Concrete product according to one of the preceding claims, characterized in that the cement slurry at least partially comprises polyurethane, in particular consists entirely of polyurethane. Concrete product according to one of the preceding claims, characterized in that the nanoparticles ( 18 ) and / or the cement matrix comprise white or bright reflecting additives and / or bright, light-reflecting aggregates and sands. Concrete product according to one of the preceding claims, characterized in that the nanoparticles ( 18 ) 5% to 30% by weight, in particular 8% to 20% by weight, of the cover layer concrete ( 16 ) turn off. Concrete product according to one of the preceding claims, characterized in that the nanoparticles ( 18 ) have a multilayer structure, in particular a construction mica metal powder / semiconductor compound, and preferably the nanoparticles ( 18 ) are doped with aluminum or another metal. Concrete product according to claim 8, characterized in that the nanoparticles ( 18 ) have a coating, in particular a mica, metal and / or an oxide coating, in particular a transparent SiO ₂ coating. Concrete product according to one of the preceding claims, characterized in that the cover layer concrete ( 16 ) has a thickness of 3 mm to 20 mm, preferably 5 mm to 10 mm. Concrete product according to one of the preceding claims, characterized in that the cover layer ( 14 ) is arbitrarily dyeable. Concrete product according to one of the preceding claims, characterized in that the cover layer ( 14 ) for exposing the infrared-reflecting nanoparticles ( 18 ) mechanically reworked, in particular ground, blasted, milled or otherwise roughened. Concrete product according to one of the preceding claims, characterized in that additional nanoparticles ( 14 ) before curing the topcoat ( 14 ) in the surface of the cover layer ( 14 ) are introduced, in particular blown, sprinkled or otherwise applied. Concrete product according to one of the preceding claims, characterized in that the cover layer ( 14 ) is provided with a planar nano-coating. Concrete product according to one of the preceding claims, characterized in that the concrete product ( 10 . 20 . 30 . 40 50 . 60 ) is a paving stone, an outer facade stone, a brick or a roof tile. Cement mixture for producing a concrete product according to one of the preceding claims, characterized in that the cement mixture infrared-reflecting nanoparticles ( 18 ) for the production of the cover layer concrete ( 16 ).

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