DE102009043662B4 - Partially translucent cementitious or polymer bonded stone slabs - Google Patents

Abstract

Partially translucent blocks made of concrete or polymer concrete, characterized in that in these plates relatively large, from the plate front to the back of the plate reaching, transparent, solid glass body are embedded with bruchsteinartig irregular shape whose Werksteinseitige interfaces with a light-reflecting coating, formed from a light-resistant, silanized and coated with titanium dioxide and / or uncoated mica flakes and / or are provided with other based on mica-based effect pigment resin and that these stone slabs on the front plan smooth and polished and ground flat on the back and with colorless-transparent and / or color toned or transparent color-coated glass particles are coated, these glass particles being present as geometrically irregularly broken glass granules and a highly transparent and light-stable resin system serves as a coating matrix.

Description

The request for protection pertains to partially or selectively translucent cementitious or polymer-bonded stone slabs. In contrast to known cementitious or polymer-bound concrete or polymer workstones, however, these panels not only contain additives which consist of a technically meaningful grading curve of fine, medium-fine and coarse grain sizes.

Partially translucent stone slabs are known. The translucent concrete (Litracon ^® ) invented by the Hungarian architect Àron Losonczy in 2001 has countless optical fiber strands embedded in a matrix of fine concrete in a very dense, filigree arrangement. The production of translucent concrete elements formed in this way, however, is technically rather complex, the products are correspondingly expensive and therefore in the context of larger architectural objects so far (as of July 2009) planned but not yet realized. Further stone slabs are from the pamphlets DE 1980932 U . DE 20 2006 000 028 U1 . DE 1757773 U and DE 1126300 B known.

The present invention is intended to offer a technically, economically and aesthetically advantageous alternative to built-in ceiling, wall or floor panels and interconnected Lichtstrahlersystemen. This object is achieved with an article according to claim 1. Applications for the subject invention are set forth in claim 9.

The transparent glass body extending from the front of the plate to the back of the plate allows light to flow from one side of the stone to the other. The stone is thus, as soon as a light source acts from one side of the plate, at the same time a luminous body with a relatively monochrome or high-contrast terrazzo-like structure and surface appearance. These are plate-shaped components made of concrete or polymer concrete, in which the light outlets in the form of translucent solid glass bodies represent a directly integrated into the building material component. An essential aspect relevant to the invention is that not every light outlet requires its own light source but that numerous light outlets can be supplied with light with only one light source.

In contrast to the optical glass fibers in the Litracon ^® these glass body not only in fine concrete but also in coarse grain containing concrete or polymer concrete -. B. with aggregates up to 15 mm grain size - be embedded. This results in a terrazzo-like appearance when the visible surface of the stone slab is ground. A primary feature of the inventive stone slabs is therefore initially that relatively large, from the front plate to the back of the plate reaching, light-transmitting, solid glass body are embedded in these plates. As a mandatory feature of the partially translucent stone slabs according to the invention, the embedded glass body are solid, as they occur in each glass breakout in the glassworks. These glass bodies are irregularly shaped like bricks - each one of them a unique piece - and come in different sizes. For example (with a thickness of the stone plate of, for example, 15-25 mm) in volume sizes of 1000 mm ³ to 250000 mm ³ . Another essential feature of the partially translucent block of stone according to the invention is that the factory-side boundary surfaces of the stored irregularly shaped solid glass body are provided with a light-reflecting coating. This has the effect that even from an acute angle incident light from the light incident surface is reflected by the factory-side boundary surfaces of the solid glass body to a high degree and directed in the direction of the light failure surface. An independently of the intensity of the incident light optically advantageous sibrig-white shimmering reflector layer is achieved by the Werksteinseitigen interfaces of the embedded solid glass body are coated with a light-stable, silanized resin, which is filled with mica flakes and / or other mica-based effect pigment.

Another essential feature of the invention is that the partially translucent stone slabs can be designed either as cementitiously bound concrete slabs or as bonded with reaction resin polymer concrete slabs.

Of particular importance for the optical properties of the partially translucent stone slabs according to the invention is the nature of the slab surfaces: The visible front side (= light outlet side) is ground and polished to a high gloss or silk gloss. The invisible back (= light inlet side), however, is preferably only roughly ground and coated with a "carpet" of colorless transparent and / or colored or transparent color coated glass particles. The binder used for such a coating is a (preferably silanized and reaction-cured) colorless or color-tinted, highly transparent and light-stable synthetic resin system, for. For example, an aliphatic polyurethane resin system. This glass particle "carpet" on the light inlet side causes a visually very interesting refraction and directional distribution of the incident light. The glass particles are as in irregular shape broken glass chippings in front. The grain size of the glass particles depends on the desired light refraction effect and is on average at least 1 mm and at most 6 mm. The thickness of the synthetic resin coating matrix is at least 20% and at most 60% of the mean grain size of the applied glass particles.

The surface portion of the embedded solid glass body on both sides of the plate can be between 5% and 70% of the total surface area of the plate. The surface area of each individual translucent glass body, which is visible on both sides of the plate and perceptible by the eye of the observer, may be between 50 mm ² and 10,000 mm ² . The solid glass bodies can be embedded in the stone slab - according to the wishes of the architect or designer - in a well-ordered pattern or in an irregular pattern or in purely random placement. The interfaces of the embedded solid glass body are preferably provided with a reaction-cured epoxy resin system. In order to achieve a high light reflection, the resin system is preferably filled with titanium dioxide-coated and / or uncoated and with titanium dioxide pigment offset mica flakes.

• a) Der innen liegende Bereich der Kunstharzbeschichtung (in diesem Fall stark lichtreflektierend gestaltet) ist über die enthaltenen Silan- bzw. Siloxanmoleküle chemoreaktiv an die werksteinseitigen Oberflächen des Massivglaskörpers gebunden.
• b) Das Beschichtungsharz ist mit (sehr hellen und nahezu transparenten) Muskovit-Glimmerschuppen angereichert. Der so gebildete „Panzer” aus einander überlagernden Schuppen bildet eine wirksame Sperrschicht: Sie verhindert, dass alkalische Einflüsse aus der zementösen Matrix des Betonwerksteins bis auf die gläsernen Oberflächen der lichtdurchlässigen Massivglaskörper vordringen können. Sie verhindert somit eine bei Durchfeuchtung der Zementmatrix an diesen Oberflächen drohende Alkali-Kieselsäure-Reaktion, die zu weissen Ausblühungen von Alkalicarbonaten + Kieselsäure und letztlich zu einer progressiven Schädigung des Verbundes zwischen den eingebetteten Massivglaskörpern und dem sie umgebenden Betonwerkstein führen würde.
• c) Der außen liegende Bereich der Kunstharzschicht auf den werksteinseitigen Kontaktflächen der eingebetteten Massivglaskörper ist im Zuge des Beschichtungsprozesses mit einem Gemisch aus Zementpulver und feinem Quarzsand abgepudert, sodass sich auch ein starker Verbund zwischen den organisch beschichteten Glaskörpern und dem hydraulisch reagierenden Zementmörtel des Betonwerksteins ergibt.

In the case of embedding the translucent solid glass body in cement-bound concrete these are provided according to the invention with a coating structure which combines in itself three functions:

• a) The inner region of the synthetic resin coating (in this case designed to be highly light-reflecting) is chemoreactively bound to the sides of the solid glass body via the silane or siloxane molecules contained.
• b) The coating resin is enriched with (very light and almost transparent) muscovite mica flakes. The so-formed "shell" of overlapping scales forms an effective barrier layer: It prevents that alkaline influences from the cementitious matrix of the concrete block can penetrate to the glass surfaces of the translucent solid glass body. It thus prevents an imminent dampening of the cement matrix at these surfaces imminent alkali-silica reaction, which would lead to white efflorescence of alkali metal carbonates + silica and ultimately to a progressive damage to the bond between the embedded solid glass bodies and the surrounding concrete block.
• c) The outer region of the synthetic resin layer on the factory-side contact surfaces of the embedded solid glass body is powdered in the course of the coating process with a mixture of cement powder and fine quartz sand, so that there is also a strong bond between the organically coated glass bodies and the hydraulically reactive cement mortar of the concrete block.

The coating thus constructed thus forms a two-sided effective bonding bridge (to the glass body on one side and to the cement matrix on the other side) and prevents (by the contained "mica scale armor") at the same time the harmful alkali-silica reaction.

As a matrix former for cementitious slabs according to the invention are modern, self-compacting and self-venting high-performance concrete systems such. B. Dyckerhoff Flowstone ^® particularly suitable: due to their high mechanical strength they allow a relatively thin design of the slab according to the invention. Natural aggregates or granules are used as aggregates in the fine grain range <2 mm, in the coarse grain range (eg 2-8 mm) natural stone chips and / or aggregates of color-coated or effect-coated glass and / or mirror glass granules.

In the case of incorporation of the translucent solid glass body in polymer bound stone matrix, the factory boundary surfaces of the solid glass body according to the invention with a light-stable, silanized resin - preferably a reaction-cured epoxy resin - coated with titanium dioxide-coated and / or uncoated and titanium dioxide pigment added with muscovite Mica flakes and / or other mica-based effect pigment is filled. The combination of mica and very light pigment causes the required light-reflecting property of the factory-facing boundary surfaces of the solid glass body.

Reaction-cured pigmented or colored epoxy resin systems or reaction-cured clear or pigmented or colored aliphatic polyurethane resin systems are preferably used as matrix formers for polymer bound partially translucent stone slabs according to the invention.

The inorganic aggregates of the stone slabs may consist of natural stone and / or of colorless and / or colored glass powder or glass granules and / or color-coated or with effect pigment-coated glass or also mirror glass granules.

uses

The partially translucent blocks of stone according to the invention are used in conjunction with natural or artificial light sources as components for double floor systems supported on stilts, as elements for exhibition stand construction, table, counter and staircase construction, for parapet and base constructions, dividing wall, partition wall and false ceiling systems, for interior wall and exterior wall cladding, as components in church construction and for objects in gardening and landscaping, in well and monument construction and in other objects of the "furnishing" of public areas and spaces usable.

drawings

The appended drawings are intended to serve the understanding of the invention and its essential characteristics without being able to give a full description of the various possible embodiments.

1 shows a perspective view of a cementitious or polymer bound stone tablet (A), in which relatively large, from the front of the plate to the back of the plate reaching, light-transmitting, solid glass body (B) are embedded. These glass bodies (B) can consist of colorless transparent or color-tinted or opaline glass.

2 shows in perspective view a light-transmitting solid glass body (B), which was made from a raw glass fragment. The front (B1) and the back (B2) are designed parallel by a post-processing.

The factory-side boundary surfaces (B3) are irregularly shaped like bricks and light-reflecting coated. This reflector coating consists of a light-resistant synthetic resin which is filled with titanium dioxide-coated and / or uncoated mica flakes and titanium dioxide as powder pigment and / or with other mica-based effect pigment.

3 illustrates in a plan view of the plate surface, the possibility of arranging the light-transmitting solid glass body (B) embedded in the stone (A) in a relatively even distribution or in a disordered placement. The surface area of the embedded glass bodies (B) on both sides of the plate may be between 5% and 50% of the total surface area of the plate. The surface area of each individual translucent glass body (B) may be between 50 mm ² and 10000 mm ² on the front and on the back.

4 shows a section through a portion of a stone slab (A), in which a light-transmitting glass body (B) is embedded. While the surface of the top (A / B1) - = "light outlet side" - is polished and polished to shine, the bottom (A / B2) - = "light inlet side" is only roughly ground and provided with a refractive coating. This coating consists of a highly transparent colorless or slightly tinted, light-stable synthetic resin layer (C), which is provided with a "carpet" of colorless-transparent and / or color-tinted or transparent color-coated glass particles (D). This glass particle "carpet" on the light inlet side causes a visually very interesting refraction and directional distribution of the incident light. The glass particles are present as irregularly broken glass chips. The grain size of the glass particles depends on the desired light refraction effect and is on average at least 1 mm and at most 6 mm. The thickness of the synthetic resin coating matrix is at least 20% and at most 60% of the average particle size of the applied glass particles.

5 shows in a highly simplified representation of the use of a stone slab according to the invention as a backlit raised floor element. The plate itself is basically constructed as in 5A that is, the light outlet side (A / B1) is finely polished and polished, the light inlet side (A / B2) is coated with a carpet of glass particles (C, D). The stone slab is supported on distance-maintaining stilts (E), which at the same time for receiving light emitters -. B. fluorescent lamps - serve. The surface of the subfloor (H) and also the vertical wall terminations of the cavity are light-reflecting - for example with profiled aluminum foil - lined (G) in order to direct as much light on the light inlet side.

Examples:

In the following, some typical application possibilities of the partially translucent stone slabs according to the invention are described briefly without any claim to completeness:

Example A: Backlit raised floor.

For an architect, a backlit double floor area was designed. A height-adjustable pedestal storage system with translucent stilts made of polycarbonate was chosen for the support. At the same time, these stilts served as a holder for light sources which were directed slightly upwards at a slight angle. The height of the stilts was set to 120 mm. The subfloor was lined with light reflecting aluminum foil. The format of the partially opaque stone tiles stored on the stilts was 800 × 800 × 20 mm. Due to the required bending tensile strength, a reaction-hardening pigmented and low-yellowing epoxy resin system was chosen as the matrix former for the stone slabs. The aggregates consisted of a grading curve of recycled glass grains, with the fine grained area of 0-2 mm consisting of silanized clear glass and the coarse grain area of 2-8 mm consisting of color-coated clear glass, in some cases color-coated mirror glass breakage. In each of these Polymerwerksteinplatten about 60 massive, from the top of the plate to the underside of the plate reaching clear glass body were stored, which were formed from irregularly shaped glass fragments. The surface size of the horizontally parallel plane cut clear glass body was on the Lichtauslass- as on the Lichteinlass side between 250 and 1200 mm ² . The completely irregular shaped factory-side boundary surfaces of the stored glass body were coated reflecting light. The top of the plate was finely ground and polished to a high degree of gloss. The underside of the slab was roughly ground and coated with a "carpet" of small clear glass fragments of 1.5-4 mm size. The coating binder used was a highly transparent aliphatic polyurethane resin.

Example B: Bar for a cocktail bar

The counter of a cocktail bar was to be constructed of polished exposed concrete elements, with numerous differently sized translucent glass bodies in irregular distribution integrated into both the horizontal top panel and the vertical front panels. The base material used was anthracite gray pigmented high-performance concrete "Dyckerhoff Flowstone ^{( R )} ", the embedded glass bodies consisted of colorless raw glass fragments coated according to the invention. The use or visible surfaces of the counter elements were polished to a high gloss and impregnated (hydrophobic). The inside surfaces were only roughly ground and coated with a "carpet" of small turquoise, blue and green colored glass fragments of 2-4 mm size. The light source for the backlighting of the elements was a system of 15 energy-saving lamps with a power consumption of 7 watts each.

Example C: fountain with sculpture

As the base for an admonishing fountain sculpture on the topic of "climate change", the artist wanted a floating hollow body that makes one think of a melting ice floe. According to the artist's ideas, the sculpture itself was supposed to represent a human hand, from whose fingertips water swells.

For the realization of the floe, the artist proposed a plate-shaped element according to the invention consisting of floatable hollow bodies of thin-walled white exposed concrete in the form of an ice floe, which in turn floats in a fountain basin. The surface of the plume top is about 2 m ² , the plan underside about 2.5 m ² , both surfaces in irregular polygonal and staggered shape. Both in the horizontal cover plate as well as in the formed from numerous plates lateral "Schollenabbruch" surfaces are stored in irregular arrangement massive glass fragments of transparent cullet in sizes between 5000 and 50,000 mm ³ . The outer sides of the horizontal cover plate and the lateral "lug break" surfaces are only roughly ground and then shot peened, so that there is a rough surface. Invisible to the viewer inner sides (backs) of the cover plate and the side plates are - as described in Examples A and C - roughly ground and coated with a "carpet" of small glass fragments of 1.5 to 4 mm size.

However, the coating binder used here is a transparent and slightly orange-tinted aliphatic polyurethane resin. As glass particles red and yellow tinted transparent glass is used: This causes the stored glass body after activation of the light sources in the interior of the floating soil - act like fiery, sweaty pores, which represent a striking contrast to the cold-acting surface color of the floe.

Claims (9)

Partially translucent blocks made of concrete or polymer concrete, characterized in that in these plates relatively large, from the plate front to the back of the plate reaching, transparent, solid glass body are embedded with bruchsteinartig irregular shape whose Werksteinseitige interfaces with a light-reflecting coating, formed from a light-resistant, silanized and coated with titanium dioxide and / or uncoated mica flakes and / or are provided with other based on mica-based effect pigment resin and that these stone slabs on the front plan smooth and polished and ground flat on the back and with colorless-transparent and / or color toned or transparent color-coated glass particles are coated, these glass particles being present as geometrically irregularly broken glass granules and a highly transparent and light-stable resin system serves as a coating matrix. Workstone slabs according to claim 1, characterized in that the surface portion of the embedded translucent glass bodies on both sides of the slab is between 5% and 50% of the total surface area of the slab and that the planar surfaces on the front and back of each individual translucent glass body are on both sides between 50 mm ² and 10000 mm ² . Work stone slabs according to one of claims 1-2, characterized in that the light-transmissive glass bodies embedded in the slab are arranged according to a specifically ordered pattern or according to a deliberately irregular pattern or in purely random placement. Work stone slabs according to one of claims 1-3, characterized in that the embedded translucent glass body consist of farblostransparentem or colored tinted, translucent solid glass. Workstone slabs according to any one of claims 1 to 4, characterized in that the grain size of the applied to the Plattenrück- or -unterseite glass particles on average at least 1 mm and at most 8 mm and the thickness of the resin coating matrix at least 20% and at most 50% of the average grain size. Work stone slabs according to one of claims 1 to 5, characterized in that a reaction-hardened colorless or color-tinted synthetic resin system serves as a coating matrix. Stone slabs according to one of claims 1-6, characterized in that the slab is a cementitious bound concrete slab, which in the fine grain <2 mm natural stone aggregates and in the coarse grain> 2 mm natural stone surcharges and / or aggregates of color-coated glass granules, coated mirror glass granules or with iridescent or luminescent effect pigments coated glass granules. Stone slabs according to any one of claims 1-6, characterized in that the slab is polymer bound, wherein a reaction-hardened pigmented epoxy resin system or a reaction-hardened glassy or pigmented aliphatic polyurethane resin system serves as a binder and the aggregates of natural stone and / or of colorless and / or colored glass flour or glass granules and / or colored coated or coated with effect pigment glass or mirror glass granules. Use of partially translucent stone slabs according to claims 1-6 and 7 or 8 in conjunction with natural or artificial light sources as components for double floor systems mounted on stilts, as elements for exhibition stand construction, table, bar and staircase or step construction, Partition wall, partition wall and false ceiling systems, for interior wall and exterior wall cladding, as components in church construction as well as for gardening and landscaping, in well and monument construction and in other objects for the "furnishing" of public areas and rooms.

Images