EP1225283B2 - Heat-insulating building element - Google Patents
Heat-insulating building element Download PDFInfo
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- EP1225283B2 EP1225283B2 EP02000346.3A EP02000346A EP1225283B2 EP 1225283 B2 EP1225283 B2 EP 1225283B2 EP 02000346 A EP02000346 A EP 02000346A EP 1225283 B2 EP1225283 B2 EP 1225283B2
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- compression elements
- building element
- contact profiles
- components
- element according
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- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B1/00—Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
- E04B1/003—Balconies; Decks
- E04B1/0038—Anchoring devices specially adapted therefor with means for preventing cold bridging
Definitions
- the invention relates to a component for thermal insulation according to the preamble of claim 1.
- Such components for thermal insulation are known in the relevant state of the art in many different versions and serve to decouple two components from each other thermally, but at the same time statically connect them together. This static connection takes place via reinforcing elements, which extend through the insulating body between the two components and safely transfer the occurring loads, ie in particular tensile, compressive and shear forces.
- An essential field of application of such components is, for example, in balconies that protrude from a building exterior wall and are suspended on said reinforcing elements on the same height ceiling with the interposition of a component for thermal insulation. Since these balconies are exposed to different temperatures than the floor slab running in each case in the insulated building interior, temperature-related relative movements occur between the two components, ie between the balcony and the floor slab. Because while the floor slab is kept at substantially the same temperature, the outside temperature and thus the temperature of the balcony slab varies depending on weather conditions and season per day by more than 10 ° C.
- the present invention is therefore based on the object to further improve the known thermal insulation element and to form it so that it is optimized in terms of manufacturing costs, adaptability to the installation condition and in terms of recording relative movements between the adjacent concrete components.
- the relative movement of two concrete components in the order of 2 mm results in a rotational movement of the pressure element relative to the adjacent concrete component in the mutual contact area with a relative movement of only 0.2 mm. From this example, it is easy to see that this significantly reduced displacement is accompanied by a correspondingly significantly reduced to a negligible amount of noise. In the same sense, the fact that part of the previous sliding or friction movement is replaced by a rolling movement.
- the contact profiles Due to the inventive shape of the contact profiles, which are convex and arched in a circular arc shape in horizontal section, results in the largest possible contact surface unimpeded and symmetrical displacement movement at both opposite contact profiles.
- the contact profiles in the installed state should be anchored in the concrete components such that the pressure elements protrude only with the curved contact profile area in the concrete components to allow the unimpeded rotational movement between the pressure element and the concrete component. This is also possible, for example, via toothed contact profiles which carry out the rolling movement by virtue of their likewise approximately arcuate curvature.
- the circular arc-shaped cross section of the contact profiles extends over the entire height thereof.
- each contact profile is designed in the form of a cylinder jacket part surface.
- the horizontal cross sections can also change over the height of the printing element, such. B. at a sheath part surface of a truncated cone. This ensures that the power transmission between the pressure element and the concrete component takes place over the entire contact profile surface.
- a preferred design of the contact profiles is that they also have a concave outer surface which is also curved in the vertical direction, that is, they are also arched in a vertical longitudinal section. This allows them to follow any vertical settlement movements between the two components without affecting their function.
- the pressure elements thus formed give way slightly articulated and are - despite a slightly inclined position compared to the horizontal installation - yet full surface with their frontal contact profiles on the adjacent concrete components.
- the printing element continuously and without offset pass into the contact profiles to keep the surface of the contact profile as small as possible and - at least approximately - only so form large, as the dimensions, ie in particular the cross section, the pressure-transmitting transmitting behind the contact profiles arranged pressure elements.
- an elastically or reversibly compliant bearing can be achieved by the printing elements according to the invention, regardless of their material, so that the advantages of the present invention in particular in printing elements of hard unyielding or high-strength material to bear.
- the pressure element must not even in the transverse direction elastically temperature-related longitudinal movements between the two adjacent components can follow, but by the rolling motion, it can also be made of high-strength material - such as concrete.
- a particularly suitable form of use of concrete printing elements results from the fact that they are made by casting, which has a great many possibilities in terms of shape and surface design of the printing elements.
- Another advantage arises when the mold consists of a plastic shell that can be installed as a lost mold together with the concrete pressure element; because then the plastic shell can simultaneously serve as a sliding layer for the pressure element in the contact area of the frontal contact profiles of the adjacent concrete components and thereby improve the Abubal Serviceenschaften the printing element even more.
- the pressure element material must not be fine-grained, closed-pored, etc., it suffices the corresponding flat surface of the plastic mold, which then rolls on the adjacent concrete component.
- cross-sectional reductions in the middle region between the two end-side contact profiles can be produced in a simple manner, which are decisive for the degree of thermal conductivity or for the heat transfer through the pressure element.
- Such cross-sectional reductions take place in the horizontal direction and / or in the vertical direction, so that the pressure element is formed in a waisted horizontal section with a tapered in the direction of the central region between the two end contact profiles and / or on the other hand, the height of the pressure element in Reduced direction of the central region between the two frontal contact profiles.
- the printing elements are produced from a lost casting mold, this can advantageously be exploited to form two continuous printing elements which form a double printing element, leaving a space between the two printing elements in which, for example, a transverse force rod can be used can be fixed to the mold. Moreover, it is also possible to fill the gap by insulating material or form as enclosed by the mold and filled with air cavity.
- FIG. 1 is a component 1 for thermal insulation fragmentary in section through the in FIG. 2 indicated level I - I.
- the component 1 is installed in a left between a concrete building A and a cantilevered concrete outer part B joint and consists essentially of a filling the filling insulator 2 and of reinforcing elements in the form of in the Figures 1 and 2 illustrated printing elements. 3
- FIG. 2 the component 1 does not show with all its parts and in its full height; rather, the upper insulating body portion carrying the commonly used tie rods, which has nothing to do with the present invention, is not shown. Also lacking the representation of a transverse force rod extending from the supporting component, the building A, in the direction of the supported component, the balcony B, obliquely from top to bottom through the insulating body or filled by the insulating joint and protrudes into both components to the transverse force introduction ,
- the pressure element 3 runs essentially horizontally through the insulating body from the component B to the component A. At the end faces 5, 6 facing the components, the pressure element 3 has arched contact profiles which act as a pressure force input and output surface and according to the in FIG FIG. 1 illustrated horizontal section are formed circular arc. Over the entire surface of the contact profiles, the overall shape of a cylinder jacket part surface results due to this circular arc shape, since the pressure element in each case has a constant cross section over the height.
- the effect of the circular arc shape is as follows: If the two components A and B relative movements from each other, so form the arcuately curved contact profiles hinge surfaces that allow the relative movement without it comes in the contact area between contact profile and adjoining concrete component to large displacement movements. As a result, the actual relative movements between the concrete components and the pressure elements can be significantly reduced and as a result one obtains pressure elements that can follow reversible and without significant noise independently of the material temperature-induced displacement movements.
- FIG. 3 An alternative design of the present invention is in FIG. 3 There is shown a component 11 for thermal insulation between a building A and a balcony B, shown in horizontal section at the level of pressure elements 13a, 13b. Between building A and balcony B also an insulating body 12 is shown, which extends along the gap left between the two components.
- the essential difference of the pressure elements 13a, 13b over the Pressure element 3 off FIG. 1 consists in the fact that in each case a pressure element is replaced by two parallel pressure elements, which require a correspondingly smaller force introduction surface in the form of contact profiles 15a, 15b, 16a, 16b. This results in a double joint similar to a parallelogram, which further reduces the displacement between the contact profiles and the adjacent concrete components.
- Both types of pressure element have, in addition to the circular arc-shaped contact profiles also very similar pressure element cross-sectional shapes, namely a continuously and without offset from the edges of the contact profiles passing gob-like outer shape, which tapers slowly to the center of the joint and then on the way to the opposite contact profile again continuously disseminated to there absatzlos in to transition the edges of the opposite contact profile.
- This shape ensures optimum introduction of force from the balcony slab B into the pressure element, optimal pressure force transmission with reduced heat conduction through the joint and optimal pressure force discharge into the building A.
- the cross sections are designed so that they are as large as possible force introduction surface and slender Druckkraftübertragungsquerroughs Construction at mutual continuous transition yet kink-resistant, stable pressure element with - due to the small cross-sectional area - still more favorable thermal insulation, especially if used as a material for the pressure element concrete.
- a lost mold 20 is shown in a perspective view, which is used for the production of pressure elements made of concrete and is used together with the concrete pressure elements in the inventive (not shown here) component for thermal insulation.
- FIGS. 7 to 13 show only the mold 20 and not the concrete pressure elements themselves; these correspond in their appearance and their arrangement about the design FIG. 3
- the lost mold is intended to be installed together with the concrete pressure elements in the device for thermal insulation, so far so the illustration is made FIG. 3 not directly to the embodiment of the FIGS. 4 to 12 transferable.
- the casting mold 20 has two cavities 21, 22 which are to be filled with concrete and which are open in the installed position, which predetermine the shape of the concrete pressure element.
- the concrete pressure elements obtained by the mold has a structure that relates both to The horizontal section as well as with respect to the vertical section to the center tapers: Using the example of the cavity 21 enclosed by the mold 20, this means that the concrete pressure element in the direction of the largest possible cross-sectional and surface in the region of the end-side curved contact profiles 23, 24 the central region 25 between the two contact profiles is tapered; based on one out FIG. 7 recognizable horizontal section or on the in FIG.
- the casting mold 20 has a connection region 26 between the two cup-shaped individual casting molds 20a, 20b surrounding the cavities 21, 22. In this connection region, a cavity 27 enclosed by the casting mold 20 is left, which is filled with air and serves as an insulating body. In the adjacent to the connecting portion 26 between the two Einzelg screenformen 20a, 20b arranged area a recess 28 for receiving a transverse force bar is provided, which dips into the space between the two pressure elements and is fixed there to the mold.
- the mold has on its outer side vertically extending webs 29, 30, which are provided to seal the lateral gap between the two molds by laterally joining an adjacent double pressure element with a correspondingly constructed mold by each of the individual webs 30 in the space between the dip both double bridges 29. In this way, it is possible to prevent liquid concrete from flowing into the intermediate space between the two casting molds and impairing their function.
- the mold 20 also has at the edge of an end-face contact profile 23 in a horizontal section T-shaped web, which is intended to project into the adjacent concrete component - in particular in an integrally formed in a precast Filigranplatte and be anchored to this form-fitting manner.
- the rolling contact profile has the disadvantage of not providing a connection in the pulling direction, which is particularly relevant during transport; Therefore, the T-shaped web 31 serves as a drawstring for the transmission of tensile forces between mold or associated printing elements and adjacent concrete component.
- the mold has on its underside hook-like latching lugs 33, which serve to lock the mold on a surrounding the device for thermal insulation on the underside of the rail and set.
- the pressure elements in the region of the contact profiles 23, 24 with their lower foot region 23a, 24a project further into the associated component (A, B) than with their upper head region 23b, 24b.
- the mold 20 functioning as a sliding layer for the contact profiles is provided with a greater thickness in the lower foot region 23a, 24a, since the stresses due to edge pressure are highest in this region.
- the present invention offers the advantage of printing elements to provide that do not have to be resilient even in the transverse direction, but are mounted elastically yielding in the transverse direction relative to the adjacent concrete components.
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Abstract
Description
Die Erfindung betrifft ein Bauelement zur Wärmedämmung nach dem Oberbegriff von Anspruch 1.The invention relates to a component for thermal insulation according to the preamble of claim 1.
Derartige Bauelemente zur Wärmedämmung sind im einschlägigen Stand der Technik in vielen verschiedenen Ausführungen bekannt und dienen dazu, zwei Bauteile wärmetechnisch voneinander zu entkoppeln, sie aber gleichzeitig statisch miteinander zu verbinden. Dieses statische Verbinden erfolgt über Bewehrungselemente, die sich durch den Isolierkörper zwischen den beiden Bauteilen erstrecken und die jeweils auftretenden Belastungen, also insbesondere Zug-, Druck- und Querkräfte, sicher übertragen.Such components for thermal insulation are known in the relevant state of the art in many different versions and serve to decouple two components from each other thermally, but at the same time statically connect them together. This static connection takes place via reinforcing elements, which extend through the insulating body between the two components and safely transfer the occurring loads, ie in particular tensile, compressive and shear forces.
Ein wesentliches Einsatzgebiet solcher Bauelemente besteht beispielsweise bei Balkonen, die gegenüber einer Gebäudeaußenwand vorstehen und über die genannten Bewehrungselemente an der höhengleichen Geschossdecke unter Zwischenfügung eines Bauelementes zur Wärmedämmung aufgehängt werden. Da diese Balkone anderen Temperaturen als die jeweils im isolierten Gebäudeinneren verlaufende Geschossdecke ausgesetzt sind, treten zwischen den beiden Bauteilen, also zwischen Balkon und Geschossdecke, temperaturbedingte Relativbewegungen auf. Denn während die Geschossdecke auf im wesentlichen gleicher Temperatur gehalten wird, schwankt die Außentemperatur und damit die Temperatur der Balkonplatte je nach Wetterlage und Jahreszeit pro Tag um mehr als 10° C.An essential field of application of such components is, for example, in balconies that protrude from a building exterior wall and are suspended on said reinforcing elements on the same height ceiling with the interposition of a component for thermal insulation. Since these balconies are exposed to different temperatures than the floor slab running in each case in the insulated building interior, temperature-related relative movements occur between the two components, ie between the balcony and the floor slab. Because while the floor slab is kept at substantially the same temperature, the outside temperature and thus the temperature of the balcony slab varies depending on weather conditions and season per day by more than 10 ° C.
Und da sich die Länge der Balkonplatte in Abhängigkeit der Temperatur ändert, müssen die die beiden Bauteile verbindenden Bewehrungselemente diese Längenänderungen unbeschadet mitmachen können. Für die üblicherweise sehr schlank ausgebildeten Zug- und Querkraftstäbe ist dies in der Regal kein Problem. Anders sieht dies aber bei den Druckstäben aus, die zur Erhöhung der Drucksteifigkeit meist relativ massiv ausgebildet sind. Aber aus der
Neben der Verwendung elastisch nachgiebiger Druckelementmaterialen ist es darüber hinaus bekannt, Druckelemente vorzusehen, deren Abmessungen der Isolierkörperdicke entsprechen, die also bündig mit dem Isolierkörper abschließen und mit ihren den Betonbauteilen zugewandten stirnseitigen Kontaktprofilen flächig an den Betonbauteilen anliegen. Werden derartige auf die Isolierkörperdicke beschränkte Druckelemente Relativbewegungen der angrenzenden Betonbauteile unterworfen, so verschieben sich Druckelement und Betonbauteile nach Überwindung der gegenseitigen Haftreibung im Bereich der Kontaktstellen zueinander. Diese Art eines reversibel nachgiebigen Druckelementanschlusses besitzt jedoch den Nachteil, dass man das erwähnte Überwinden der Haftreibung und die anschließende Relativverschiebung in Form von Knackgeräuschen hört, die zwar eigentlich harmlos sind und keine Rückschlüsse auf die Qualität der eingebauten Druckelemente bzw. deren Lagerung zulässt, die auf der anderen Seite aber trotzdem unerwünscht und für den unkundigen Bewohner doch auch Anlass zur Sorge sind.In addition to the use of elastically resilient pressure element materials, it is also known to provide pressure elements whose dimensions correspond to the Isolierkörperdicke, so flush with the insulator and rest with their concrete components facing frontal contact profiles surface on the concrete components. If such pressure elements limited to the insulating body thickness are subjected to relative movements of the adjoining concrete components, the pressure element and the concrete components move towards one another after overcoming the mutual static friction in the area of the contact points. However, this type of reversibly compliant pressure element connection has the disadvantage that one hears the mentioned overcoming the static friction and the subsequent relative displacement in the form of pops, which are actually harmless and no conclusions on the quality of the built-in printing elements or their storage allows on the other side but still undesirable and for the unkown residents but also cause for concern.
Im Stand der Technik ist darüber hinaus beispielsweise aus der
Hiervon ausgehend liegt somit der vorliegenden Erfindung die Aufgabe zugrunde, das bekannte Bauelement zur Wärmedämmung weiter zu verbessern und es so auszubilden, dass es hinsichtlich Herstellungskosten, Anpassbarkeit an die Einbaugegebenheit sowie hinsichtlich der Aufnahme von Relativbewegungen zwischen den angrenzenden Betonbauteilen optimiert ist.Proceeding from this, the present invention is therefore based on the object to further improve the known thermal insulation element and to form it so that it is optimized in terms of manufacturing costs, adaptability to the installation condition and in terms of recording relative movements between the adjacent concrete components.
Diese Aufgabe wird erfindungsgemäß gelöst durch die Merkmale von Anspruch 1.This object is achieved by the features of claim 1.
Hierbei erhält man unabhängig vom Druckelementmaterial eine Gelenkverbindung, also selbst bei hochfesten starren Werkstoffen wie dem erfindungsgemäßen hochfesten Beton. Die sich hierbei ergebende pendelgelenkartige Schwenkbewegung führt zu einer erheblichen Reduzierung des tatsächlichen Verschiebewegs. Bei einem exemplarischen Ausführungsbeispiel ergibt die Relativbewegung zweier Betonbauteile in der Größenordnung von 2 mm eine Drehbewegung des Druckelements gegenüber dem angrenzenden Betonbauteil im gegenseitigen Anlagebereich mit einer Relativbewegung von nur 0,2 mm. An diesem Beispiel ist unschwer erkennbar, dass dieser deutlich reduzierte Verschiebeweg mit einem entsprechend deutlich auf eine vernachlässigbare Größe reduzierten Geräuschaufkommen einhergeht. In gleichem Sinn wirkt die Tatsache, dass ein Teil der bisherigen Gleit- bzw. Reibbewegung ersetzt wird durch eine Abrollbewegung.In this case, regardless of the printing element material, a joint is obtained, that is, even in the case of high-strength rigid materials such as the high-strength concrete according to the invention. The resulting pendulum joint-like pivoting movement leads to a significant reduction of the actual displacement. In an exemplary embodiment, the relative movement of two concrete components in the order of 2 mm results in a rotational movement of the pressure element relative to the adjacent concrete component in the mutual contact area with a relative movement of only 0.2 mm. From this example, it is easy to see that this significantly reduced displacement is accompanied by a correspondingly significantly reduced to a negligible amount of noise. In the same sense, the fact that part of the previous sliding or friction movement is replaced by a rolling movement.
Es sind zwar im Stand der Technik bereits Druckelemente mit gewölbten Kontaktprofilen bzw. Stirnseiten bekannt: So offenbart z. B. die
Durch die erfindungsgemäße Form der Kontaktprofile, die konvex und im Horizontalschnitt kreisbogenförmig gewölbt ausgebildet sind, ergibt sich erst bei größtmöglicher Anlagefläche eine ungehinderte und symmetrische Verschiebewegung an beiden gegenüberliegenden Kontaktprofilen. Darüber hinaus sollten die Kontaktprofile im Einbauzustand derart in den Betonbauteilen verankert sein, dass die Druckelemente nur mit dem gekrümmten Kontaktprofilbereich in die Betonbauteile vorstehen, um die ungehinderte Drehbewegung zwischen Druckelement und Betonbauteil zuzulassen. Dies ist beispielsweise auch über verzahnte Kontaktprofile möglich, die durch ihre ebenfalls etwa kreisbogenförmige Wölbung die Abrollbewegung durchführen.Due to the inventive shape of the contact profiles, which are convex and arched in a circular arc shape in horizontal section, results in the largest possible contact surface unimpeded and symmetrical displacement movement at both opposite contact profiles. In addition, the contact profiles in the installed state should be anchored in the concrete components such that the pressure elements protrude only with the curved contact profile area in the concrete components to allow the unimpeded rotational movement between the pressure element and the concrete component. This is also possible, for example, via toothed contact profiles which carry out the rolling movement by virtue of their likewise approximately arcuate curvature.
Zweckmäßigerweise erstreckt sich der kreisbogenförmige Querschnitt der Kontaktprofile über deren gesamte Höhe. Eine diesbezügliche Möglichkeit besteht beispielsweise darin, dass jedes Kontaktprofil in Form einer Zylindermantelteilfläche ausgebildet ist. Darüber hinaus können sich die Horizontalquerschnitte aber auch über die Höhe des Druckelementes ändern, wie z. B. bei einer Mantelteilfläche eines Kegelstumpfes. So ist sichergestellt, dass die Kraftübertragung zwischen Druckelement und Betonbauteil über die gesamte Kontaktprofilfläche erfolgt.Conveniently, the circular arc-shaped cross section of the contact profiles extends over the entire height thereof. There is a possibility in this regard for example, in that each contact profile is designed in the form of a cylinder jacket part surface. In addition, the horizontal cross sections can also change over the height of the printing element, such. B. at a sheath part surface of a truncated cone. This ensures that the power transmission between the pressure element and the concrete component takes place over the entire contact profile surface.
Schließlich besteht eine bevorzugte Bauform der Kontaktprofile noch darin, dass diese eine auch in Vertikalrichtung insbesondere konkav gewölbte Außenfläche aufweisen, also auch im vertikalen Längsschnitt gewölbt sind. Hierdurch können sie etwaigen vertikalen Setzungsbewegungen zwischen den beiden Bauteilen ohne Beeinträchtigung ihrer Funktion folgen. Die so geformten Druckelemente geben hierbei leicht gelenkartig nach und liegen - trotz einer leicht geneigten Schrägstellung im Vergleich zur horizontalen Einbauanlage - dennoch vollflächig mit ihren stirnseitigen Kontaktprofilen an den angrenzenden Betonbauteilen an.Finally, a preferred design of the contact profiles is that they also have a concave outer surface which is also curved in the vertical direction, that is, they are also arched in a vertical longitudinal section. This allows them to follow any vertical settlement movements between the two components without affecting their function. The pressure elements thus formed give way slightly articulated and are - despite a slightly inclined position compared to the horizontal installation - yet full surface with their frontal contact profiles on the adjacent concrete components.
Es empfiehlt sich des weiteren, dass die Druckelement kontinuierlich und absatzlos (im Gegensatz zu den bekannten Bauformen mit großflächigen angefügten Druckplatten zur Krafteinleitung) in die Kontaktprofile übergehen, um die Fläche des Kontaktprofils möglichst klein halten zu können und sie - zumindest in etwa - nur so groß auszubilden, wie die Abmessungen, also insbesondere der Querschnitt, der druckkraftübertragenden hinter den Kontaktprofilen angeordneten Druckelemente sind.It is further recommended that the printing element continuously and without offset (in contrast to the known types with large-scale attached pressure plates for force introduction) pass into the contact profiles to keep the surface of the contact profile as small as possible and - at least approximately - only so form large, as the dimensions, ie in particular the cross section, the pressure-transmitting transmitting behind the contact profiles arranged pressure elements.
Wie bereits vorstehend erwähnt, lässt sich eine elastisch bzw. reversibel nachgiebige Lagerung durch die erfindungsgemäßen Druckelemente unabhängig von deren Material erzielen, so dass die Vorteile der vorliegenden Erfindung insbesondere bei Druckelementen aus hartem unnachgiebigen bzw. hochfestem Material zum Tragen kommen.As already mentioned above, an elastically or reversibly compliant bearing can be achieved by the printing elements according to the invention, regardless of their material, so that the advantages of the present invention in particular in printing elements of hard unyielding or high-strength material to bear.
Beton ist zwar im Stand der Technik bereits des öfteren als Material für Druckelemente vorgeschlagen worden, hat sich in der Praxis aber nicht durchsetzen können. Ein diesbezügliches Hindernis ist durch die vorliegende Erfindung ausgeräumt: Nun muss das Druckelement nicht selbst in Querrichtung elastisch temperaturbedingten Längsbewegungen zwischen den beiden angrenzenden Bauteilen folgen können, sondern durch die Abwälzbewegung kann es auch aus hochfestem Material - wie eben beispielsweise Beton - bestehen.Although concrete has been frequently proposed in the prior art as a material for printing elements, but has not been able to prevail in practice. A related obstacle is eliminated by the present invention: Now, the pressure element must not even in the transverse direction elastically temperature-related longitudinal movements between the two adjacent components can follow, but by the rolling motion, it can also be made of high-strength material - such as concrete.
Eine besonders geeignete Verwendungsform von Beton-Druckelementen ergibt sich dadurch, dass diese durch Gießen hergestellt sind, wodurch man sehr viele Möglichkeiten im Bezug auf Form und Oberflächengestaltung der Druckelemente besitzt. Ein weiterer Vorteil ergibt sich dann, wenn die Gießform aus einer Kunststoffschale besteht, die als verlorene Gießform zusammen mit dem BetonDruckelement eingebaut werden kann; denn dann kann die Kunststoffschale gleichzeitig als Gleitschicht für das Druckelement im Anlagebereich der stirnseitigen Kontaktprofile an die angrenzenden Betonbauteile dienen und hierdurch die Abwälzeigenschaften des Druckelements noch verbessern. Somit muss also das Druckelementmaterial nicht feinstkörnig, geschlossenporig etc. ausgebildet sein, es reicht die entsprechende ebene Oberfläche der Kunststoffgießform, die sich dann am angrenzenden Betonbauteil abwälzt.A particularly suitable form of use of concrete printing elements results from the fact that they are made by casting, which has a great many possibilities in terms of shape and surface design of the printing elements. Another advantage arises when the mold consists of a plastic shell that can be installed as a lost mold together with the concrete pressure element; because then the plastic shell can simultaneously serve as a sliding layer for the pressure element in the contact area of the frontal contact profiles of the adjacent concrete components and thereby improve the Abwälzeigenschaften the printing element even more. Thus, therefore, the pressure element material must not be fine-grained, closed-pored, etc., it suffices the corresponding flat surface of the plastic mold, which then rolls on the adjacent concrete component.
Es ist zwar bereits aus der
Stellt man nun die Druckelemente durch Gießen her, dann lassen sich in einfacher Weise Querschnittsreduzierungen im mittleren Bereich zwischen den beiden stirnseitigen Kontaktprofilen erzeugt, die ausschlaggebend sind für das Maß der Wärmeleitfähigkeit bzw. für den Wärmedurchgang durch das Druckelement. Solche Querschnittsreduzierungen erfolgen in Horizontalrichtung und/oder in Vertikalrichtung, so dass das Druckelement zum einen im Horizontalschnitt tailliert ausgebildet ist mit einem sich in Richtung des mittleren Bereichs zwischen den zwei stirnseitigen Kontaktprofilen verjüngenden Querschnitt und/oder dass zum anderen sich auch die Höhe des Druckelements in Richtung des mittleren Bereichs zwischen den beiden stirnseitigen Kontaktprofilen reduziert.If the pressure elements are now produced by casting, cross-sectional reductions in the middle region between the two end-side contact profiles can be produced in a simple manner, which are decisive for the degree of thermal conductivity or for the heat transfer through the pressure element. Such cross-sectional reductions take place in the horizontal direction and / or in the vertical direction, so that the pressure element is formed in a waisted horizontal section with a tapered in the direction of the central region between the two end contact profiles and / or on the other hand, the height of the pressure element in Reduced direction of the central region between the two frontal contact profiles.
Werden die Druckelemente aus einer verlorenen Gießform hergestellt, so lässt sich dies vorteilhafterweise dazu ausnutzen, dass über eine durchgehende Gießform zwei Druckelemente miteinander verbunden sind, die ein Doppeldruckelement bilden, wobei zwischen den beiden Druckelementen ein Zwischenraum belassen ist, in dem beispielsweise ein Querkraftstab einsetzbar und an der Gießform fixierbar ist. Darüber hinaus ist es auch möglich, den Zwischenraum durch Isoliermaterial auszufüllen oder als von der Gießform umschlossener und mit Luft gefüllter Hohlraum auszubilden.If the printing elements are produced from a lost casting mold, this can advantageously be exploited to form two continuous printing elements which form a double printing element, leaving a space between the two printing elements in which, for example, a transverse force rod can be used can be fixed to the mold. Moreover, it is also possible to fill the gap by insulating material or form as enclosed by the mold and filled with air cavity.
Weitere Merkmale und Vorteile der vorliegenden Erfindung ergeben sich aus der nachfolgenden Beschreibung von Ausführungsbeispielen anhand der Zeichnungen; hierbei zeigen
- Figur 1
- ein Bauelement zur Wärmedämmung mit erfindungsgemäßem Druckelement in einem Horizontalschnitt;
Figur 2- das Bauelement aus
Figur 1 in geschnittener Seitenansicht; Figur 3- eine alternative Ausführungsform eines Bauelements zur Wärmedämmung mit erfindungsgemäßem Druckelement in geschnittener Draufsicht.
- Figuren 4 bis 6
- eine Gießform für ein erfindungsgemäßes Doppeldruckelement in verschiedenen perspektivischen Ansichten;
- Figur 7
- eine Draufsicht auf die Gießform aus den
Figuren 4 bis 6 ; - Figur 8
- eine Seitenansicht der Gießform;
Figur 9- eine Darstellung entlang der Schnittebene A-A aus
Figur 7 ; - Figur 10
- eine Schnittdarstellung entlang der Schnittebene B-B aus
Figur 7 ; Figur 11- eine Schnittdarstellung entlang der Ebene C-C aus
Figur 8 ; Figur 12- eine Schnittdarstellung entlang der Ebene D-D aus
Figur 8 ; und - Figur 13
- eine Ansicht der Gießform von unten.
- FIG. 1
- a device for thermal insulation with inventive pressure element in a horizontal section;
- FIG. 2
- the component
FIG. 1 in a sectional side view; - FIG. 3
- an alternative embodiment of a device for thermal insulation with inventive pressure element in a sectional plan view.
- FIGS. 4 to 6
- a mold for a double pressure element according to the invention in different perspective views;
- FIG. 7
- a plan view of the mold from the
FIGS. 4 to 6 ; - FIG. 8
- a side view of the mold;
- FIG. 9
- a representation along the cutting plane AA
FIG. 7 ; - FIG. 10
- a sectional view along the section plane BB
FIG. 7 ; - FIG. 11
- a sectional view taken along the plane CC
FIG. 8 ; - FIG. 12
- a sectional view along the plane DD
FIG. 8 ; and - FIG. 13
- a view of the mold from below.
In
Es sei angemerkt, dass
Das erfindungsgemäße Druckelement 3 verläuft im Wesentlichen horizontal durch den Isolierkörper vom Bauteil B zum Bauteil A. An den den Bauteilen zugewandten Stirnseiten 5, 6 weist das Druckelement 3 gewölbte Kontaktprofile auf, die als Druckkraftein- bzw. -ausleitungsfläche fungieren und gemäß dem in
Der Effekt der Kreisbogenform ist folgender: Führen die beiden Bauteile A und B Relativbewegungen zueinander aus, so bilden die kreisbogenförmig gewölbten Kontaktprofile Gelenkflächen, die die Relativbewegung zulassen, ohne dass es im Anlagebereich zwischen Kontaktprofil und angrenzendem Betonbauteil zu großen Verschiebebewegungen kommt. Hierdurch lassen sich die tatsächlichen Relativbewegungen zwischen den Betonbauteilen und den Druckelementen deutlich reduzieren und als Ergebnis erhält man Druckelemente, die unabhängig vom Material temperaturbedingten Verschiebebewegungen reversibel und ohne wesentliche Geräuschentwicklung folgen können. Denn während die Relatiwerschiebung bei bündig mit dem Isolierkörper verlaufenden Druckelementen aufgrund der wirksamen Kräfte, der gängigen Oberflächenrauhigkeiten und der üblicherweise doch recht großen Verschiebelänge zu einer deutlichen Geräuschentwicklung führen, sorgt die gelenkartige Ausbildung der Verbindungsstellen zwischen Kontaktprofil und Betonbauteilen für eine erhebliche Reduzierung der Länge des Verschiebeweges, was sich eben dadurch auszeichnet, dass eine nur noch vernachlässigbare Neigung zu den durch die Überwindung der Haftreibung entstehenden Knackgeräuschen vorliegt.The effect of the circular arc shape is as follows: If the two components A and B relative movements from each other, so form the arcuately curved contact profiles hinge surfaces that allow the relative movement without it comes in the contact area between contact profile and adjoining concrete component to large displacement movements. As a result, the actual relative movements between the concrete components and the pressure elements can be significantly reduced and as a result one obtains pressure elements that can follow reversible and without significant noise independently of the material temperature-induced displacement movements. Because while Relatiwerschiebung lead in flush with the insulating body extending pressure elements due to the effective forces, the usual surface roughness and the usually quite large displacement length to a significant noise, the articulated formation of the joints between contact profile and concrete components for a significant reduction in the length of the displacement , which is characterized by the fact that there is only a negligible inclination to the cracking noise resulting from overcoming the static friction.
Eine alternative Bauform der vorliegenden Erfindung ist in
Der wesentliche Unterschied der Druckelemente 13a, 13b gegenüber dem Druckelement 3 aus
Beide Druckelementbauformen weisen neben der kreisbogenförmig ausgebildeten Kontaktprofile auch sehr ähnliche Druckelementquerschnittsformen auf, nämlich eine kontinuierlich und absatzlos von den Rändern der Kontaktprofile übergehende kelchartige Außenform, die sich zur Fugenmitte langsam verjüngt und anschließend auf dem Weg zum gegenüberliegenden Kontaktprofil wieder kontinuierlich verbreiteter, um dort absatzlos in die Ränder des gegenüberliegenden Kontaktprofils überzugehen. Diese Form gewährleistet eine optimale Krafteinleitung von der Balkonplatte B in das Druckelement, eine optimale Druckkraftübertragung bei reduzierter Wärmeleitung durch die Fuge und eine optimale Druckkraftausleitung in das Gebäude A. Die Querschnitte sind hierbei so gestaltet, dass sie sich bei möglichst großer Krafteinleitungsfläche und möglichst schlanker Druckkraftübertragungsquerschnittsfläche bei gegenseitigem kontinuierlichem Übergang ein dennoch knickfestes, stabiles Druckelement mit - aufgrund der geringen Querschnittsfläche - dennoch günstiger Wärmedämmung gibt, insbesondere wenn als Material für das Druckelement Beton verwendet wird.Both types of pressure element have, in addition to the circular arc-shaped contact profiles also very similar pressure element cross-sectional shapes, namely a continuously and without offset from the edges of the contact profiles passing gob-like outer shape, which tapers slowly to the center of the joint and then on the way to the opposite contact profile again continuously disseminated to there absatzlos in to transition the edges of the opposite contact profile. This shape ensures optimum introduction of force from the balcony slab B into the pressure element, optimal pressure force transmission with reduced heat conduction through the joint and optimal pressure force discharge into the building A. The cross sections are designed so that they are as large as possible force introduction surface and slender Druckkraftübertragungsquerschnittsfläche at mutual continuous transition yet kink-resistant, stable pressure element with - due to the small cross-sectional area - still more favorable thermal insulation, especially if used as a material for the pressure element concrete.
In den
Auch die
Die Gießform 20 weist zwei mit Beton zu verfüllende und in Einbaulage nach unten offene Hohlräume 21, 22 auf, die die Form des Beton-Druckelementes vorgeben. Obwohl die beiden Betondruckelemente durch eine Gießform miteinander verbunden sind, weisen sie selbst keine direkte Verbindung auf, das heißt der Beton beschränkt sich tatsächlich auf die Hohlräume 21, 22 ohne Verbindungsstege etc. Die Betondruckelemente erhalten durch die Gießform einen Aufbau, der sich sowohl bezogen auf den Horizontalschnitt als auch bezogen auf den Vertikalschnitt zur Mitte hin verjüngt: Am Beispiel des von der Gießform 20 umschlossenen Hohlraums 21 heißt dies, dass das Betondruckelement ausgehend von einer möglichst großen Querschnitts- und Oberfläche im Bereich der stirnseitigen gewölbten Kontaktprofile 23, 24 in Richtung auf den mittleren Bereich 25 zwischen den beiden Kontaktprofilen sich verjüngend ausgebildet ist; bezogen auf einen aus
Die Gießform 20 weist einen Verbindungsbereich 26 zwischen den beiden die Hohlräume 21, 22 umgebenden becherförmigen Einzelgießformen 20a, 20b auf. In diesem Verbindungsbereich ist ein von der Gießform 20 umschlossener Hohlraum 27 belassen, der mit Luft gefüllt ist und als Isolierkörper dient. Im benachbart zum Verbindungsbereich 26 zwischen den beiden Einzelgießformen 20a, 20b angeordneten Bereich ist eine Aussparung 28 zur Aufnahme eines Querkraftstabes vorgesehen, welcher in den Zwischenraum zwischen die beiden Druckelemente eintaucht und dort an der Gießform festgelegt ist.The casting
Die Gießform weist an ihrer Außenseite vertikal verlaufende Stege 29, 30 auf, die dazu vorgesehen sind, bei seitlichem Anfügen eines benachbarten Doppeldruckelements mit entsprechend aufgebauter Gießform dadurch den gegenseitigen Zwischenraum zwischen den beiden Gießformen abzudichten, indem jeweils die einzelnen Stege 30 in den Zwischenraum zwischen die beiden Doppelstege 29 eintauchen. So lässt sich verhindern, dass flüssiger Beton in den Zwischenraum zwischen die beiden Gießformen fliesst und deren Funktion beeinträchtigt.The mold has on its outer side vertically extending
Die Gießform 20 weist darüber hinaus am Rand eines stirnseitigen Kontaktprofils 23 einen im Horizontalschnitt T-förmigen Steg auf, der dazu vorgesehen ist, in das angrenzende Betonbauteil - insbesondere in eine in einem Fertigteilwerk angeformte Filigranplatte vorzustehen und mit dieser formschlüssig verankert zu werden. Denn im Gegensatz zu bisherigen Druckelementbauformen, die formschlüssig in den angrenzenden Betonbauteilen verankert waren, besitzt das sich abwälzende Kontaktprofil den Nachteil, keine Verbindung in Zugrichtung zur Verfügung zu stellen, was insbesondere beim Transport relevant ist; deshalb dient der T-förmige Steg 31 als Zugband zur Übertragung von Zugkräften zwischen Gießform bzw. zugeordneten Druckelementen und angrenzendem Betonbauteil.The
Schließlich fällt bei Betrachtung der
Schließlich weist die Gießform an ihrer Unterseite hakenartige Rastnasen 33 auf, die dazu dienen, die Gießform an einer das Bauelement zur Wärmedämmung auf dessen Unterseite umgebenden Schiene zu verrasten und festzulegen.Finally, the mold has on its underside hook-like latching lugs 33, which serve to lock the mold on a surrounding the device for thermal insulation on the underside of the rail and set.
Es sei noch erwähnt, dass die Druckelemente im Bereich der Kontaktprofile 23, 24 mit ihrem unteren Fußbereich 23a, 24a weiter in das zugehörige Bauteil (A, B) vorstehen als mit ihrem oberen Kopfbereich 23b, 24b. Darüber hinaus ist die als Gleitschicht für die Kontaktprofile fungierende Gießform 20 im unteren Fußbereich 23a, 24a mit einer größeren Dicke versehen, da in diesem Bereich die Belastungen infolge Kantenpressung am höchsten sind.It should be mentioned that the pressure elements in the region of the contact profiles 23, 24 with their
Zusammenfassend bietet die vorliegende Erfindung den Vorteil, Druckelemente zur Verfügung zu stellen, die nicht selbst in Querrichtung elastisch nachgiebig sein müssen, sondern die in Querrichtung gegenüber den angrenzenden Betonbauteilen elastisch nachgiebig gelagert sind.In summary, the present invention offers the advantage of printing elements to provide that do not have to be resilient even in the transverse direction, but are mounted elastically yielding in the transverse direction relative to the adjacent concrete components.
Claims (10)
- Building element for providing thermal insulation between two components, especially between a building (A) and a projecting exterior part (B), the building element comprising an insulator body (2, 12) to be arranged between the two components, the insulator body (2, 12) having at least integrated compression elements (3, 13a, 13b) which, in the installed state of the building element (1, 11), can extend through the insulator body substantially horizontally and transversely with respect to the substantially horizontal longitudinal extent thereof and which are each connectible to both components (A, B), the compression elements having a convexly curved contact profile (5, 6, 15a, 15b, 16a, 16b) which is able to roll on the components (A, B), so that the compression elements are able to form an articulated connection between the two components, the curved portion of the contact profiles (5, 6, 15a, 15b, 16a, 16b), in the installed state, being approximately in the shape of an arc of a circle in horizontal section and the compression elements being so constructed that only their convexly curved contact profiles project relative to the insulator body (2, 12) into the concrete components,
characterised in
that the compression elements (3, 13a, 13b) consist of high-strength concrete, and that the compression elements are provided with a sliding layer (20) in the region of their end-face contact profiles (23, 24),
that the compression elements (3, 13a, 13b) are waisted in horizontal section, with a cross-section that is reduced in the central region (25) between the two endface contact profiles (23, 24) and/or
that the compression elements, in their central region (25) between the two end-face contact profiles (23, 24), are reduced in height relative to the contact profiles. - Building element according to claim 1,
characterised in that
the sliding layer is thicker in the lower foot region (23a, 23b) of the contact profiles (23, 24). - Building element according to at least one of the preceding claims,
characterised in that
the compression elements are so constructed that, starting from the edges of the contact profiles (5, 6, 15a, 15b, 16a, 16b), they merge continuously and steplessly into the central region of the compression element. - Building element according to at least one of the preceding claims,
characterised in that
the compression elements (3, 13a, 13b) are able, by means of their curved contact profiles (5, 6, 15a, 15b, 16a, 16b), to follow the relative movements between the two components (A, B) by virtue of the contact profiles performing a pivoting movement relative to their associated component in the manner of a pendulum joint. - Building element according to at least one of the preceding claims,
characterised in that
in the region of the contact profiles (23, 24), the lower foot region (23a, 24a) - of the compression elements extends further into the associated component (A, B) than does the upper head region (23b, 24b). - Building element according to at least claim 1,
characterised in that
the sliding layer consists of a lost mould (20) for the compression element produced from concrete. - Building element according to at least one of the preceding claims,
characterised in that
the contact profiles (5, 6, 15a, 15b, 16a, 16b), in the installed state, are anchorable in the components (A, B). - Building element according to at least one of the preceding claims,
characterised in that
the end-face contact profiles (23, 24) of the compression elements are curved, especially concavely curved, in vertical longitudinal section. - Building element according to at least one of the preceding claims,
characterised in that
two compression elements are connected to one another by way of a connection region (26). - Building element according to at least claim 9,
characterised in that
a transverse load bar is insertable between the two compression elements and is fixable thereto.
Priority Applications (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP06006831A EP1669501A1 (en) | 2001-01-23 | 2002-01-04 | Heat-insulating building element |
PL351806A PL207113B1 (en) | 2001-01-23 | 2002-01-22 | Thermal insulation carring structural member |
JP2002014412A JP3920102B2 (en) | 2001-01-23 | 2002-01-23 | Thermal insulation structure unit |
CZ2002-282A CZ304661B6 (en) | 2001-01-23 | 2002-01-23 | Building element for thermal insulation between two building parts |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
DE10102930A DE10102930A1 (en) | 2001-01-23 | 2001-01-23 | Component for thermal insulation |
DE10102930 | 2001-01-23 |
Related Child Applications (2)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP06006831A Division-Into EP1669501A1 (en) | 2001-01-23 | 2002-01-04 | Heat-insulating building element |
EP06006831A Division EP1669501A1 (en) | 2001-01-23 | 2002-01-04 | Heat-insulating building element |
Publications (3)
Publication Number | Publication Date |
---|---|
EP1225283A1 EP1225283A1 (en) | 2002-07-24 |
EP1225283B1 EP1225283B1 (en) | 2008-02-20 |
EP1225283B2 true EP1225283B2 (en) | 2014-10-29 |
Family
ID=7671472
Family Applications (2)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP06006831A Withdrawn EP1669501A1 (en) | 2001-01-23 | 2002-01-04 | Heat-insulating building element |
EP02000346.3A Expired - Lifetime EP1225283B2 (en) | 2001-01-23 | 2002-01-04 | Heat-insulating building element |
Family Applications Before (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP06006831A Withdrawn EP1669501A1 (en) | 2001-01-23 | 2002-01-04 | Heat-insulating building element |
Country Status (4)
Country | Link |
---|---|
EP (2) | EP1669501A1 (en) |
AT (1) | ATE386850T1 (en) |
DE (2) | DE10102930A1 (en) |
DK (1) | DK1225283T4 (en) |
Families Citing this family (10)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP1564336B1 (en) * | 2004-02-11 | 2007-09-19 | HALFEN GmbH | Thermally insulating construction element |
DE102004020914B4 (en) * | 2004-04-28 | 2008-05-29 | Max Frank Gmbh & Co Kg | cantilever panel |
DE102008029701A1 (en) | 2008-06-24 | 2009-12-31 | Schöck Bauteile GmbH | Component for thermal insulation and insulation material for construction applications |
US8991124B2 (en) | 2008-10-17 | 2015-03-31 | Schöck Bauteile GmbH | Concrete material, construction element for a thermal insulation, and brick-shaped thermally insulating element, each using the concrete material |
PL2742191T3 (en) | 2011-08-11 | 2017-08-31 | Schöck Bauteile GmbH | Structural element for heat-insulating purposes |
DE102011122589A1 (en) | 2011-12-30 | 2013-07-04 | Schöck Bauteile GmbH | Component for thermal insulation |
DE102012012912A1 (en) | 2012-06-29 | 2014-04-10 | Schöck Bauteile GmbH | Component for thermal insulation |
DE202013006229U1 (en) * | 2013-07-11 | 2014-10-13 | H-Bau Technik Gmbh | Thermally insulating component |
EP3385462B1 (en) * | 2017-04-05 | 2020-03-04 | HALFEN GmbH | Thermally insulating component |
DE102017118745A1 (en) | 2017-08-17 | 2019-04-11 | Schöck Bauteile GmbH | Component for thermal insulation |
Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP0034332A2 (en) † | 1980-02-14 | 1981-08-26 | Eberhard Schöck | Construction element for heat insulation of buildings |
DE3422905A1 (en) † | 1984-06-20 | 1986-01-02 | Hansjörg Dipl.-Ing. 7542 Schömberg Braun | Apparatus for connecting a balcony slab and an intermediate floor |
DE4009987C2 (en) † | 1990-03-28 | 1995-08-24 | Schoeck Bauteile Gmbh | Thermal insulation component |
DE19508292A1 (en) † | 1995-03-09 | 1996-09-12 | Rolf Hirn | Structural element for thermal insulation between concrete building and cantilevered section |
DE19652165A1 (en) † | 1996-12-05 | 1998-06-18 | Syspro Gruppe Betonbauteile E | Insulating support body for overhanging balcony |
EP0933482A2 (en) † | 1998-01-28 | 1999-08-04 | Syspro-Gruppe Betonbauteile e.V. | Prefabricated element for cantilevered balcony slab |
Family Cites Families (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE3116381C2 (en) * | 1981-04-24 | 1983-04-28 | Eberhard Ing. Schöck (grad.), 7570 Baden-Baden | Pressure element in a heat-insulating prefabricated component for projecting parts of the building |
DE3309254A1 (en) | 1983-03-15 | 1984-10-04 | Manfred Dierichs | PRINTING ELEMENT IN A HEAT-INSULATING COMPONENT FOR PROJECTING BUILDING PARTS |
DE9410288U1 (en) * | 1993-12-22 | 1994-10-13 | Frank Gmbh & Co Kg Max | Balcony connection |
DE29505093U1 (en) * | 1995-03-25 | 1995-05-18 | Dennert Kg Veit | Precast concrete balcony |
DE19627342B4 (en) * | 1996-06-29 | 2006-06-22 | Schöck Bauteile GmbH | Component for thermal insulation |
DE19711813C2 (en) * | 1997-03-21 | 2000-03-09 | Fraunhofer Ges Forschung | Thermally insulating component |
DE19741027A1 (en) * | 1997-09-18 | 1999-03-25 | Schoeck Bauteile Gmbh | Heat-insulating building component |
DE20010770U1 (en) * | 2000-06-13 | 2000-09-21 | Diesler Joerg | Highly insulating reinforcement cage with heat-insulating reinforcement elements |
-
2001
- 2001-01-23 DE DE10102930A patent/DE10102930A1/en not_active Ceased
-
2002
- 2002-01-04 EP EP06006831A patent/EP1669501A1/en not_active Withdrawn
- 2002-01-04 DK DK02000346.3T patent/DK1225283T4/en active
- 2002-01-04 DE DE50211716T patent/DE50211716D1/en not_active Expired - Lifetime
- 2002-01-04 AT AT02000346T patent/ATE386850T1/en active
- 2002-01-04 EP EP02000346.3A patent/EP1225283B2/en not_active Expired - Lifetime
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EP0034332A2 (en) † | 1980-02-14 | 1981-08-26 | Eberhard Schöck | Construction element for heat insulation of buildings |
DE3422905A1 (en) † | 1984-06-20 | 1986-01-02 | Hansjörg Dipl.-Ing. 7542 Schömberg Braun | Apparatus for connecting a balcony slab and an intermediate floor |
DE4009987C2 (en) † | 1990-03-28 | 1995-08-24 | Schoeck Bauteile Gmbh | Thermal insulation component |
DE19508292A1 (en) † | 1995-03-09 | 1996-09-12 | Rolf Hirn | Structural element for thermal insulation between concrete building and cantilevered section |
DE19652165A1 (en) † | 1996-12-05 | 1998-06-18 | Syspro Gruppe Betonbauteile E | Insulating support body for overhanging balcony |
EP0933482A2 (en) † | 1998-01-28 | 1999-08-04 | Syspro-Gruppe Betonbauteile e.V. | Prefabricated element for cantilevered balcony slab |
Non-Patent Citations (1)
Title |
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H-Bau Tecknik: Prospekt"Die neue Generation ist ISOPRO" 2001 Allgemeine bauaufsichtlichen Zulassung Nr. Z-15.7-185 des Deutsches Institut für Bautechnik † |
Also Published As
Publication number | Publication date |
---|---|
DE10102930A1 (en) | 2002-07-25 |
EP1225283B1 (en) | 2008-02-20 |
ATE386850T1 (en) | 2008-03-15 |
DK1225283T4 (en) | 2015-02-02 |
EP1669501A1 (en) | 2006-06-14 |
DE50211716D1 (en) | 2008-04-03 |
DK1225283T3 (en) | 2008-06-23 |
EP1225283A1 (en) | 2002-07-24 |
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EP1754840B1 (en) | Building element for heat insulation |
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