DE102014110916A1 - Wall panel heating - Google Patents

Abstract

Building panel, comprising a support structure and a wear layer, wherein the support structure comprises a matrix of fiber material, in which a binder is incorporated and wherein the wear layer is disposed on the support structure and wherein in the surface of the wear layer, a groove structure is embossed.

Description

The invention relates to a building board.

From the DE 20 2010 010 199 U1 is a layer structure for exterior walls known. The layer structure comprises a base layer, which may be formed of clay. From the DE 102 17 185 A1 is a clay building board known in which clay is integrated into a reinforcement made of wood wool.

Ecological building materials have the advantage that less chemicals are introduced into the building. Thus, these building materials have no negative impact on the health of users and residents. Furthermore, materials made of ecological building materials can be easily recycled.

In this context, ecological building materials are especially clay and lime-based building materials. In addition to avoiding the emission of chemicals, clay also has excellent building physics properties that improve the indoor climate and thus increase the well-being of users and residents. For example, loam has a high heat storage capacity and has the ability to regulate the indoor humidity by storing and releasing water. In addition, clay has shielding properties against electromagnetic radiation.

However, in clay-based construction products, processing is often difficult. For example, the successful application of a wall plaster made of clay depends, inter alia, on the surface structure of the substrate, the absorbency of the substrate, the surface temperature of the substrate, the surface moisture of the substrate, the temperature of the room air, the humidity of the room air during and after the application of the plaster and the composition of the plaster itself and its shrinkage during drying. Changes in these conditions during the clay's drying process affect successful application as well.

Furthermore, it is essential for processing whether additional components such as reinforcing mesh or tubes, pipes, cables, for example, fluid-driven or electrical wall heaters are to be introduced into the clay. Overall, it is therefore difficult to apply a clay plaster without training and even for experienced craftsmen.

Another problem is that clay hardens only by drying, with each millimeter of clay can be expected with a drying time of 24 hours. This means that a wall construction with a layer thickness of 21 mm requires a drying time of 3 weeks. In addition, during drying a lot of moisture is introduced into the building.

As insulation in the new construction of energy plus houses, passive houses and low energy houses 30 to 40 cm thick insulation packages are currently applied to the outside of the building. These usually consist of polystyrene or other petroleum-based building materials, which have the disadvantage that they can not be recycled for recycling.

For the interior of new buildings, the walls are usually plastered for cost reasons or built in drywall with plasterboard. As a rule, a wallpaper is then applied and painted this with binder color. In terms of building physics, these building materials can neither absorb nor give off moisture, which is why the room air is usually too humid in summer and too dry in winter. The result is an unhealthy room climate, the users or residents get sick faster.

Buildings constructed or rebuilt according to the generally accepted rules of technology should be free of thermal bridges. In the case of renovation, external insulation is often unjustifiable from a design or economic point of view. Here it is conceivable to use internal insulation. These, however, involve building physics problems: they have to be built due to the dew point shift and the consequent condensation of water with an absolutely dense water vapor diffusion barrier, but in practice this does not provide a permanent safe solution. The moisture stored in the heated and thus warmer indoor air precipitates in the layers becoming colder outside. The components are moistened and it comes to the formation of mold and loss of the load capacity of the components. Accordingly, old buildings were often not insulated and it has come to terms with energy losses.

Most of the heaters are fired with oil or natural gas. The problem here is that these fossil fuels are not available indefinitely. It can be expected that before the end of the life of a house, about 80 years on average, the world's fossil fuel reserves will be used up.

For heating the room air are mostly radiators or Konvektorplattenheizkörper used. These heat almost exclusively the air that flows from the radiators, while flows from below cold air. in this connection is disadvantageous that the user or occupant only feels the heat when it flows down from the upper layer again. So it takes a long time until heat is felt. Furthermore, the permanent air movement can cause unpleasant drafts. In transitional periods, the radiators are charged with lower temperatures, as a result of which the radiators become less warm and the convection of the air slows down. The heating system is sluggish and the efficiency of the introduced energy deteriorates. With the rising air also dust is whirled up from the ground. This is especially problematic for allergy sufferers.

Underfloor heating systems are also problematic and have an effect, inter alia due to the unfavorable heat distribution on the blood circulation of the feet and legs of the users or residents and thus favor water retention and varicose veins. Furthermore, underfloor heating systems are located deep in the screed and have to heat them before the user or the resident feels heat. Conversely, the underfloor heating system cools only slowly, since the surrounding screed acts as a heat storage. Underfloor heating systems are sluggish.

Also known are water-guided wall heaters, designed as wet variants and drywall variants. The wet variant brings with it the same problems as the application of a clay plaster. In addition, the layer thickness of the wall structure must be increased by the thickness of the pipe. The cover must be applied as a second layer, which extends the drying time accordingly. The dry variant is impractical in terms of processing, as previously an exact allowance of the walls has to be created and the boards can not be flexibly cut on the construction site. Another problem is the connections between the heating pipes at the transition from one plate to the next. Each joint presents a potential leak and reduces the flow rate of the medium.

In the case of electrical resistance heating, attaching the cables to a wall to be plastered afterwards is tedious and expensive. To achieve a complete embedding, it is necessary to first fill the wall and then let it dry. Then the cable must be mechanically applied or glued. Due to the installation torque of the cable two people are required for this, one who winds the Aufstellmoment from the cable and one who fixes the cable. Power cables of an electrical resistance heater can not be shortened, so they must be brought completely to the wall. If the cable is not completely processed on the wall provided or the wall is so tight that not the entire surface is covered, the cable must be removed again and the time-consuming laying work must be done again. Only when the cables have been laid correctly on the wall can the application of the plaster be started.

The invention has for its object to provide a building board, which can be combined in a particularly simple and space-saving with a heating system.

This object is achieved with the features of claim 1. In advantageous embodiments, the dependent claims relate.

According to the application of the clay plaster is greatly simplified, since the clay plaster is fixed as a plate on the wall. This eliminates drying times omitted because the plates are processed dry.

The invention simplifies the attachment of a clay plaster on wall, ceiling and slope, thereby allowing the inclusion of a heating system and the distortion of cables in the plate. The outstanding physical properties of the clay plaster are used and, in addition, the support structure achieves capillary-active internal insulation.

Clay and natural Faserarmierungen can be recycled without residue in the case of recycling the natural cycle. Clay and the reinforcement made of natural fiber absorb moisture from the room air, store it and return it if the room humidity is too low. Thus, the indoor air has a pleasant and healthy humidity in every season.

The plate can be optionally equipped with a wall heater. This radiant heat does not heat the air, but rather the illuminated surfaces. In terms of building physics, thermal bridges are less important because only the heated air escapes via thermal bridges, not the radiant heat.

Clay has very good capillary conductivity. Unusual moisture, which is produced in vapor diffusion conductive interior insulation, can thus be directed into the plate and from there into the room air. The (small) proportion of the heat of a built-in wall heating, which is not emitted as radiant heat, heats the interior of the plate and thus additionally counteracts the moisture loss in the inner insulation.

Preferably comes as a heat transfer electrical resistance heater used. In particular, the use of renewable energies results in sustainable heating.

Due to the high proportion of radiant heat, wall heaters ensure a comfortable indoor climate despite lower air temperatures. Accordingly, less insulation is needed. Due to the low convection effect, dust is hardly raised. In deeper layers of the air, the air remains cooler and the blood circulation is not adversely affected by too high temperatures in the foot area. The radiation heating according to the invention is located just below the surface of the building board, so that only a small layer thickness has to be heated before the heating effect can be felt. Radiant heat does not heat the air, which is then transported by convection, but the illuminated surfaces. As a result, radiant heaters are almost free of inertia. Even in transitional periods, the radiant heater achieves high efficiency.

The problems associated with the installation of a wall heater are achieved according to the invention by clamping the cables of an electric wall heater or the hoses or pipes of a fluid-guided wall heater in the surface of the structured plate provided with regular depressions. This eliminates the need to attach the heating components with brackets, clamps or adhesive tapes.

The surface structure described above preferably continues from one plate to the next across the plates. By full coverage of the wall with plates thereby a continuous installation level is created. An oversize is eliminated and the panels can be adapted in place to the required geometry. A production of special sizes can be omitted.

The invention allows through the additionally created near-surface installation level a simplified and much faster installation for cables of an electric heater, for hoses or pipes of fluid-driven heating and also for all other in the wall or ceiling to be forgiven cables.

Preferably, the cables, pipes or hoses are held by frictional connection in the surface structure of the building board. This can be done by pinching the installation material. In addition, the cables, tubes or hoses can also be firmly bonded by gluing. Overall, the fixation of the tubular, tubular or cable-shaped media can be achieved quickly and by a single person and corrected quickly and easily if necessary.

It is advantageous that the continuity of the installation level on site, the course of the media of the wall heating, taking into account the technical conditions and standards can be chosen freely.

Furthermore, the length of the tubes and hoses of fluid-operated heaters can be freely selected taking into account the hydraulic conditions and no longer has to be chosen according to the geometry of the room and the drywall panels. Thus it can be prevented that clutches are under the plaster. Fluid-guided systems can also be used for cooling, the hoses and pipes can also be laid in the plate.

In an advantageous embodiment, the cables of an electric wall heating through the groove structure can be laid so that the effect of a Faraday cage results, which shields, inter alia, cell phone reception. Clay additionally supports this shielding effect.

Overall, the building board according to the invention has various advantages. By using a prefabricated building board, the drying times of a plaster are reduced. In addition, the building board allows the regulation of the humidity of the room, a capillary-active water pipe, reduced installation times of a wall or ceiling heating system and a flexibilization of the pipe, hose and cable management.

An advantageous building board comprises a support structure with a matrix of fiber material, in particular of natural fibers, preferably with moisture-absorbing properties. Such a material is for example wood wool. The matrix of natural fibers is preferably in the form of a random and forms the Faserarmierung. This matrix is mixed with a binder, preferably clay or loam. In this case, the binder is introduced so that results in a little compressed structure with air inclusions. Due to the trapped air, the support construction achieves good insulation values and at the same time good flexural strength. The large surface of the support structure ensures a fast and uniform bonding process of the binder. Water of the binder is quickly absorbed into the fiber reinforcement and can be released gradually. This results in an advantageous course of drying.

In principle, it is also conceivable to impress the groove structure directly into the support structure. In this case, the wear layer can be omitted.

On the support structure, a wear layer is arranged. The wear layer is also made of clay and is applied fresh in fresh on the support structure. In the fresh clay, the groove structure according to the invention is coined. The groove structure can be rectangular or elliptical or have other geometric shapes. Preferably, grooves in the longitudinal direction and transverse direction at the same distances. The distances can be brought to a predetermined level for an electrical resistance heater.

In an advantageous embodiment, the groove structure is designed in the form of the pattern of a chocolate bar. Also conceivable is the pattern of a waffle iron. The grooves may be V-shaped or rectangular. Furthermore, the grooves may also be semicircular or rectangular in shape with a semicircular base. Between the grooves arise elevations, which are formed depending on the configuration of the grooves rectangular, oval, round or the like.

The grooves form a receptacle for the components of the wall heating. In the case of the V-shaped grooves, the components can first be frictionally fixed by clamping, so that simplifies the assembly.

The support structure acts decoupling between wear layer and substrate.

It is also preferred to specify distances which are required for the laying of hoses or pipes of a fluid-guided heating system. Preferably, these are the same and the grooves can be used both for the cables of electrical resistance heaters and for hoses or pipes of fluid-guided systems.

When processing the plate, the grooves serve as Schneideraster. The structure of longitudinal and transverse grooves also offers advantages in the manufacturing process, as a given crack pattern is created in the wear layer of loam and wild shrinkage cracks in the wear layer are avoided. The cracks can reach into the supporting structure without mechanically weakening the board and ensuring a consistent surface quality.

The groove structure gives the plate a larger surface and dries faster.

In an endless production can be cut at any point along the longitudinal and transverse grooves, so that can be freely assembled in the grid.

In an advantageous embodiment, the building board is provided at the edges with a stepped rebate. The stepped rabbet is designed so that two adjacent plates can be arranged overlapping. For this purpose, the edges of two adjacent edges may be formed so that the front portion protrudes, while the edges of the other two edges are formed so that each of the rear portion protrudes. The stepped rebate simplifies assembly and stability of the wall construction once again.

If both support structure and wear layer made of the same material or binder or binders with the same or very similar setting properties, this has a favorable effect on the setting process, this can be accelerated by drying, unwanted unplanations are avoided, even if no additional moisture in Drying process is supplied.

By a V-shaped cross-section of the grooves and the application of radii in longitudinal section either narrower cables of an electrical resistance heater or the hoses or pipes of fluid-driven heating or cooling can be laid in the same groove. A V-shaped cross section of the grooves ensures the best possible embedding of the media in the cover layer, which has a positive effect on the heating power.

Beveled edges in the production process lead to increased edge stability.

Radii simplify correct laying and the rounded corners lead to increased corner stability in the production process.

The structural panel according to the invention comprises a support structure made of a natural fibrous material, preferably wood wool, preferably in random orientation or several angularly introduced layers bonded with a suitable binder, preferably natural and capillary active binder, preferably loam or clay, wherein on the surface of the plate a wear layer , preferably made of clay, which is provided with recesses for receiving a heating system or cables, preferably screened in rectangular, elliptical or other geometric shapes.

A connection between support structure and surface is achieved by cohesive connection of the fibrous surface of the support structure with the wet wear layer.

The building board according to the invention can be fixed to the wall or to the ceiling of a building become. On the building board, a cover layer can be applied, in this case, the plate forms an intermediate layer between the wall and cover layer.

In a first embodiment, the plate is formed so that the grooves are suitable for receiving cables and improve the connection of the cover layer. The grooves may also be formed so that only the cover layer is fixed.

In a further embodiment, the plate is formed so that it has grooves for receiving fluid-carrying hoses or pipes or wider cables and the cover layer.

In an advantageous embodiment, the recesses are V-shaped, so that narrower cables in the deeper area and wider hoses or pipes or cables in the less deep area find support.

In an advantageous embodiment, the recesses follow radii, so that between the recesses protruding fields of the wear layer arise with round corners.

In a further advantageous embodiment, the grids in the longitudinal and transverse directions are the same, so that the plate can be installed independent of direction and independent of the laying direction of the optionally introduced heating.

In the recesses cables, hoses or pipes can be freely and preferably meander-shaped, laid according to the specifications of the heating installation and then covered with the cover layer.

The plates are attached to the existing wall, slope or ceiling, preferably the inside of the outer wall, preferably by screwing and / or gluing. It is also conceivable assembly by screws on the framework.

The building board can consist of a homogeneous mixture of binder, fiber reinforcement and aggregate.

The binder may be capillary active.

The binder may be clay.

The fiber reinforcement can be capillary active.

The fiber reinforcement can be wood wool or another natural fiber.

The supplement can be capillary active.

The supplement may include burnt and ground clay.

The plate may be at least two layers and comprise a support structure and a wear layer.

The support structure may consist of a homogeneous mixture of binder, fiber reinforcement and aggregate.

On the support structure may be arranged a wear layer of a homogeneous mass.

The homogeneous mass of the wear layer may be a capillary active plaster.

The capillary-active plaster can be made of clay.

The support structure and the wear layer can be positively connected to each other. If the support structure and the wear layer are applied wet-on-wet, a cohesive bond results.

The binder may be gypsum, lime, cement, bitumen or other binder.

The fiber reinforcement may be fiberglass, carbon fiber, textile fiber, cellulose, hemp, straw, coconut, miscanthus or other natural or artificial fiber.

The supplement may be sand, expanded glass, expanded clay, foam glass, cork, wax, gypsum, calcium silicate, plastic, expanded or extruded plastic or another natural or artificial aggregate.

The homogeneous material may be plastic, expanded or extruded plastic, calcium silicate, gypsum, lime, wood or a wood fiber material or other monolithic material.

The homogeneous material may be a plastic or metal foil.

The film may be a thermoforming film.

Some embodiments of the plate according to the invention are explained below with reference to the figures. These show, in each case schematically:

1 a plate consisting of a support structure made of binder bonded pulp in random position and a wear layer with square raster groove structure with V-shaped cross section with partially inserted thin cable electrical resistance heating and partially applied cover layer in perspective and gate;

2 a plate according to 1 with partially inserted hose of a fluid-driven heating and partially applied cover layer in a perspective view and gate;

The figures show a plate 1 , in particular for the installation of a cover layer 4 , For example, a plaster, for example made of clay. The plate comprises a support structure 2 and a wear layer 3 for receiving a cover layer 4 with the possibility of receiving cable or tubular media 5 For example, the cables of an electrical resistance heater or the hoses or pipes of a fluid-driven heating, before application of the cover layer 4 ,

The building board comprises a support structure 6 with a matrix 7 from a natural fiber material, wood wool in this embodiment. The matrix is in the form of a disorder. Into the matrix 7 is a binder 8th , introduced clay in this embodiment. Here is the binder 8th only slightly compacted, so that in the support structure 6 a variety of air pockets 9 available.

On the support structure 6 is a wear layer 10 attached, which also consists of clay.

Both in the binder 8th as well as in the wear layer 10 made of loam, the aggregate is fired and ground clay. Clay also has capillary-active properties and supports the drying process.

In the wear layer 10 is a groove structure 11 brought in. The groove structure 11 includes recesses which are V-shaped in this embodiment. The groove structure 11 serves on the one hand the inclusion of components of a heater, such as cables of an electrical resistance heater and on the other hand, the improved fixation of the cover layer 4 , The groove structure 11 can do so in the wear layer 10 be imprinted that results in a regular grid with interposed rectangular elevations. Such a pattern has the shape of a chocolate bar. In other embodiments, the groove structure 11 be formed so that there are elliptical elevations.

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 202010010199 U1 [0002]
• DE 10217185 A1 [0002]

Claims (10)

Building board ( 1 ), characterized in that at least one of the two surfaces has a groove structure. Building board according to claim 1, characterized in that the groove structure is screened. Building board according to claim 1 or 2, characterized in that the grid of the groove structure is rectangular, honeycomb-shaped or elliptical. Building panel according to claim 1 to 3, characterized in that the groove structure protruding fields ( 3 ) encloses. Building board according to claim 1 to 4, characterized in that the projecting fields ( 3 ) Have radii. Building board according to claim 1 to 5, characterized in that the groove structure continues across all bumps from a first building panel to another building panel. Building board according to claim 1 to 6, characterized in that the groove structure has a V-shaped, U-shaped or dovetailed or formed in any other geometric shape cross-section. Building board according to one of claims 1 to 7, characterized in that the building board consists of a homogeneous material or mixture.  Building panel, comprising a support structure and a wear layer, wherein the support structure comprises a matrix of fiber material, in which a binder is incorporated and wherein the wear layer is disposed on the support structure and wherein in the surface of the wear layer, a groove structure is embossed.  Wall heating system, comprising a building panel according to one of the preceding claims and a conduit system of an electric or a water-carrying heater, which is fixed in the groove structure of the wear layer.

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