DE10347578A1 - Dachstein, which contains at least two layers - Google Patents

Abstract

The invention relates to a roof tile, which consists of two layers or layers. The bottom layer is a concrete roof tile blank, while the top layer is a coating containing at least sand and a binder. The sand in the coating has grains of different sizes. The diameter of the largest grains is at most equal to the thickness of the coating, while the smallest grains have a diameter which is at least one third of the thickness of the coating.

Description

The The invention relates to a roof tile according to the preamble of the claim 1.

For roofing become common Concrete roof tiles used, consisting of a hydraulic binder, cement, and a mineral aggregate. The production of these concrete roof tiles is usually carried out in extruded or extrusion processes, wherein beaver tails, rebate roof tiles and pans arise.

at This extrusion process is continuous on sub-forms Applied concrete layer and then by means of shaping roller and smoother compacted and optionally profiled. The compacted fresh concrete layer will follow in a cutting station to roof tile fittings of the same length with a head-end and a foot-side Edge cut, with the foot side Edge is made.

The Concrete roof tiles produced by this process have both on the head-side edge as well as on the foot-side edge a cut surface, the with pores and other irregularities is provided. The roughness and porosity of these cut surfaces are much larger than that of the compacted top, so that accordingly the end faces of this Concrete roof tiles a worse quality than the compacted top exhibit. Furthermore these cut surfaces tend reinforced to efflorescence.

A method for the production of concrete roof tiles is already known, with which the foot-side edge of these tiles is better weather resistance and strength and also the efflorescence is avoided at this point ( DE 35 22 846 C3 ). Here, when cutting the fresh concrete layer of the foot-side edge portion is precompressed, and during trimming, a further material compaction is made at the foot-side edge of the Dachstein molding within at least 2 to 8 mm deep edge zone adjacent to the end face. In addition, by this material compaction out of the lower, the lower mold adjacent cutting edge outgoing and extending up to the top of the fitting rounding or bevel generated. The roof tiles produced by this extrusion process have a relatively rough surface on their exposed to weathering top. This promotes the settlement of algae, lichens and mosses.

However, it is also an extrusion process known, with which one receives products consisting of two superimposed layers of mortar of different composition and properties ( US 5 017 320 ). With this method, concrete roof tiles can be produced which have a coating. Characteristic of this method is that successive and independent extrusion of mortar or concrete. This is done with the help of two successively arranged forming stations whose molds are matched in profile from each other. In the first forming station, the concrete mixture is extruded by means of a spiked shaft and a profiled molding tool under high pressure on the lower molds. In the second forming station, a coating composition is extruded onto the profiled fresh concrete strand in the same way. By this coating mass prevents microorganisms spread on the surface of roof tiles and a strong contamination of this surface occurs.

Another method for the production of a concrete tile with an extruded and / or rolled surface coating is known from DE 39 32 573 C2 known. The concrete roof tile here consists of a base layer in the form of a mixture of hydraulic binders, such as Portland cement, sand and water as well as a coating up to several millimeters thick based on hydraulic binders, the coating can be applied in the plastic state. The concrete roof tile has on all surface areas - except on the side facing away from the weathering underside - the extruded and / or rolled-on coating and any additional layers. The coating as such contains: cement, sand with a sieving line up to 2 mm, cement-compatible, polymeric compounds from by polymerization of unsaturated, monomeric compounds, fillers and water in the ratio 1: 1.2 to 3.5: 0.5 to 0 , 05: 0.15 to 0.03: 0.60 to 0.22 and dyes with color additions in the usual amount of addition.

Of the Invention is based on the object, a coating for roof tiles and the like to provide the improved rheological properties has.

These Task is performed according to the characteristics of Patent claim 1 solved.

The invention thus relates to a roof tile, which consists of two layers or layers. The bottom layer is a concrete roof tile blank, while the top layer is a coating containing at least sand and a binder. The sand in the coating has grains of different sizes. The diameter of the largest grains is at most equal to the thickness of the coating, while the smallest grains have a diameter which is at least one third of the thickness of the coating.

Of the obtained with the invention advantage is in particular that the coating almost free of forces can be applied on a concrete tile blank and also dimensionally stable is. The properties, concerning the phenomena, which at a deformation or flow under the action of external forces, the so-called rheological properties are significantly improved. By the almost power-free Applying the layer material mixtures are avoided. Because the second layer on a mechanically not very stable body is applied, a low extrusion resistance is important. In addition, can be reduce the thickness of the coating down to 1 mm, resulting in a considerable savings in the coating composition and a corresponding Lowering material costs leads. Although the coating material can be applied in a very small layer thickness is guaranteed you still a complete and high-quality sealing especially the surface of a Dachstein. For profiled roof stones, the freshly applied flows Coating compound not from the arched areas of the center brim and the Deckfalzes down into the waterways of the Dachstein.

The Invention is based on the following representations in the Individual described. Show it:

1 a graph of the extrusion resistance as a function of the ratio layer thickness S _ext to maximum diameter of a sand grain D _{max sand} in a sand _mixture ;

2 a graph of the extrusion resistance as a function of the ratio of the height of the extrusion gap of an extrusion _machine to the maximum diameter D _{max sand} in a sand _mixture ;

3 a schematic representation of the method for producing roof tiles and for applying a coating on the surface of these tiles.

The 1 shows the extrusion _{resistance as} a function of the ratio of the desired coating _thickness S _ext to the maximum diameter D _max sand of a grain of sand in a sand grain _mixture , once under conventional conditions and once according to the invention. The upper curve I represents the conventional conditions, while the lower curve II represents the conditions according to the invention. Conventionally means that only sand and water are mixed together, while in the invention sand, water and cement are mixed together. The sand mixture used contains in both cases in equal distribution grains of sand from a predetermined minimum size to a predetermined maximum size.

As can be seen from the curve II, when using a sand particle with a diameter D _max , which is half as large as the layer thickness S _ext to be applied, the coating composition has a relatively low extrusion resistance AU (= arbitrary units), if there is no overlap of the Grain range of the cement and the fillers with that of the sand are. For S _ext is in the graph of the 1 assumed a thickness of 1 mm. This relatively low extrusion resistance is surprising because normally the extrusion resistance at a maximum grain of D _max = 0.5 times the layer thickness passes through a maximum - as the curve I shows - and thus is particularly unfavorable in terms of the destruction of the sensitive surface of the fresh concrete strand , An explanation of the surprising effect could be that the properties of the failure granules compensate for the law of strand extrusion. The thickness S _{ext of} the coating must be kept within very narrow limits during extrusion in order to obtain the curve II. When the layer thickness reaches three times the largest grain diameter, the fine mortar begins to flow. An inadequate definition of the sealing structures and impairment of the aesthetic appearance of the Dachstein are the result. It is therefore not possible to choose the ratio S _ext : D _maxSand to "7", although there the extrusion _{resistance is} even lower.

Sinks contrast, the layer thickness below 1.5 times the maximum grain diameter, find one increasing separation of cement paste - a non-solid mixture made of cement and water - and Sand takes place, and the surface quality deteriorates drastically. overlap the grading curve of the cements and fillers with the grading curve of sand, the tendency to blistering increases sharply. Tries to compensate for bubble formation by water reduction of the mixture, the extrusion resistance increases strongly. Under Sieblinie is here the particle size distribution a bulk material understood.

In the 2 the extrusion resistance is again plotted against the ratio of size of the extrusion gap and the maximum diameter of the sand. It can be seen that the curve is similar to the curve in 1 Has. This was to be expected because the extrusion gap determines the coating thickness.

The effect described above has also set in experiments in which the from DE 35 22 846 C3 known concrete roof blanks were coated in the region of the round section. For this purpose, a second forming station for extruding the coating composition and a second cutting station were installed, in which the extruded coating mass strand was divided by a second round cut knife. The separation of the coating composition strand was carried out in the region of the gap filled with the coating composition between two blanks each adjacent to the sub-molding strand.

In the 3 this is shown schematically in more detail, with the letters A to K certain positions of a plant for the production of roof tiles are called.

With A is a position designating extrudable concrete for the Production of the basic body supplied to a Dachstein becomes.

Position B indicates a first toolbox 1 at which the extrusion of the base body takes place with underlay tools.

At position C is a closed sublayer strand 2 , At position D is a first cutting station 3 provided where the main body with a profiled straight cut knife 4 and with a lower layer round cut knife 5 is cut. At position E becomes a gap 6 opened for cutting waste. Position F shows the finished basic body 7 a Dachstein. At position G, the gap in the strand is closed again. Subsequently, at position H is a forming station 8th provided with a strand upper layer material is extruded by means Oberschichtwerkzeugen on the body. At position I, there is a strand on a top layer on the main body, with the gap 11 between two basic bodies 9 . 10 closed is.

At position J there is a second cutting station on which the top layer is fitted with a standard straight cut knife 12 as well as with a heated or water-sprayed upper layer round cut knife 13 is cut.

at Position K is the finished extruded, two-ply concrete roof tile with complete covered in a round shape.

Claims (18)

Dachstein, which contains at least two layers, of which one layer is a base body and the other layer is a coating on this base body, wherein the coating contains at least sand and a binder, characterized in that the diameter of the largest grain of the sand maximally the same size the thickness of the coating is at least a third thereof. Dachstein according to claim 1, characterized that the grain size of the binder and do not overlap the grain area size of the sand. Dachstein according to claim 1, characterized that the grain size distribution of the binder and the particle size distribution of the sand do not overlap more than 10%. Dachstein according to claim 1, characterized that the coating has a thickness of 0.5 to 3 mm. Dachstein according to claim 1, characterized that the coating on the body has the same thickness everywhere. Dachstein according to claim 1, characterized that the binder is a mixture of at least two substances contains. Dachstein according to claim 6, characterized the binder contains Portland cement and fly ash. Dachstein according to claim 6, characterized that the binder contains Portland cement and limestone powder. Dachstein according to claim 1, characterized that the binder is blastfurnace slag contains. Dachstein according to claim 1, characterized that the coating has a binder glue. Dachstein according to claim 10, characterized that the binder cement is made of cement and water. Dachstein according to claim 1 and claim 10, characterized characterized in that the volume of the binder core is larger as the pore volume of the sand. Dachstein according to claim 1, characterized that a liquefier is provided, which consists of polycarboxylate ether. Dachstein according to claim 1, characterized in that the coating 0.5% to 2.5% contains mineral pigments. Dachstein according to claim 1, characterized in that the base body has a density of> 2.15 g / cm ³ . Dachstein according to claim 1, characterized that the coating before and during the extrusion has the following components: a) 100 parts Quartz sand with grains of sand of a diameter between 0.1 and 0.6 mm b) 70 parts Portland cement c) 14 parts of fly ash with a grain less than 80 mm or 14 parts of limestone powder of the same grain size d) 3 parts iron oxide pigment e) 1 part of concrete liquefier Class of polycarboxylate ether f) 35 parts water. Dachstein according to claim 1, characterized that the main body before and during the extrusion has the following components: a) 100 parts River sand of the grain 0-4 mm b) 25 parts Portland cement c) 1 part iron oxide pigment d) 10 parts water. Dachstein according to claim 16 and claim 17, characterized characterized in that the Portland cement to the class CEM I 42.5 or CEM II AS belongs.