WO2008113346A2 - System of constructional elements for thermal insulation - Google Patents

Abstract

The invention relates to a system of constructional elements for thermal insulation which consists of thermally insulating constructional elements of different dimensions. The thermally insulating constructional elements are mounted between two constructional elements to be concreted and consist of respective thermally insulating bodies to be interposed and having integrated pressure elements, tension members and shearing force members. The thermally insulating constructional elements are modularized for different loads, the ratio and/or number of reinforcement elements in the thermally insulating constructional elements varying. The angle of inclination of the shearing force members is reduced with substantially constant height and increasing thickness of the thermally insulating bodies and the ratio and/or number of tension members of the respective thermally insulating constructional element is designed and modularized in such a manner that the rated value of the tensile force that can be absorbed by the tension members is smaller than the rated value of the maximum pressure force acting upon the pressure elements by the value of the tensile force that can be passed into the adjacent supporting constructional element, which force is a result of the rated value of the tensile force that can be absorbed by at least one shearing force member and its angle of inclination.

Description

 Component system for thermal insulation

Technical area

The invention relates to a component system for thermal insulation, consisting of components for thermal insulation of different dimensions, wherein the components for thermal insulation between two components to be concreted, in particular between a supported component and a supporting component of a building, are installed and each at least to be arranged therebetween a thermally insulating Body consist of integrated pressure elements, tensile bars and shear bars, which traverse the thermally insulating body and can be connected to both components, wherein the components for thermal insulation for different load cases are elemental by the proportion and / or the number of reinforcing elements in the components for thermal insulation varied.

State of the art

Such component systems for thermal insulation and their components for thermal insulation are known in the relevant prior art in many different versions. With them, two components are thermally decoupled from each other in order to reduce the thermal bridge in this area, but at the same time statically connected to each other. This static connection takes place via reinforcing elements, in particular pressure elements, tensile bars and transverse force bars, which extend through a thermally insulating body, commonly referred to as insulation body or insulator, extend and embed in the adjacent components. The reinforcing elements transmit the loads occurring by the supported component, in particular pressure, tensile and transverse forces, on the supporting component.

The known component systems for thermal insulation consist of components for thermal insulation, which have different dimensions and different reinforcement proportions. The reinforcement parts of the reinforcement elements are defined by their length and their circumference, hence by their volume, and by their number. Since the loads caused by the supported component on the thermal insulation component change depending on the embodiment of the supported component, the proportions of the reinforcement elements necessary for the transmission of the loads vary. The component systems for thermal insulation therefore consist of components for thermal insulation which are designed for different load cases and thus for different levels of stress and denied. The components for thermal insulation are divided into different load groups, which is characterized by the maximum absorbable load of the integrated reinforcing elements and their number or proportions. Depending on the load group, the components therefore have a defined number or proportion of tensile bars, transverse force bars and pressure elements, wherein the number or proportion of transverse force bars within the load group is variable, since the reinforcing elements of the components are designed and elemented for thermal insulation, that the design value of the absorbable tensile force of the tensile bars essentially corresponds to the rated value of the compressible compressive force of the pressure elements or for strongly over-sized pressure elements that the design value of the absorbable tensile force of Zugkraftstäbe corresponds to the design value of the maximum compressive force acting on the pressure elements, resulting from the recordable loads of Component for thermal insulation results.

An essential field of application of such components for thermal insulation consists, for example, in a worn outer component, for example, a projecting balcony plate, which protrudes from a thermally insulated building exterior wall and is connected to a located in the thermally insulating building interior supporting inner component, such as a ceiling plate, with the interposition of a component for thermal insulation. However, all known embodiments of a component for thermal insulation only inadequate thermal protection, which often just barely corresponds to the minimum heat protection and thus should only prevent structural damage. This is partly due to the low insulation thickness, therefore, a small width or thickness of the thermally insulating body, the components for thermal insulation due, since it is not possible because of the damping thickness of the components for thermal insulation to match the typical today thicknesses of the insulation of the building exterior wall Therefore, the components for thermal insulation in itself when installed form thermal bridges, which just by the use of the components for thermal insulation in the Field of application should be reduced to a minimum. There is therefore no sufficient thermal separation between the outer and inner components or between the supported and the supporting components.

Since thermal bridges are recorded in the energy balance of a building, especially in low-energy houses, the resulting energy losses must be compensated by multiple insulation of other parts of the building. The resulting overhead increases the cost of construction and deteriorates the economy of the building, which is why almost no use in the construction of Niedrigstenergiehäusern, especially passive houses, which have very high insulation thickness of the building exterior wall insulation, thermal insulation components. In addition, the insufficient thermal separation results in increased energy losses, resulting in increased heating costs and increased climate-damaging carbon dioxide emissions.

The low insulation thicknesses of the known from the prior art component systems for thermal insulation are due, inter alia, to the execution or design of the transverse force rods and the interpretation and elementation of integrated in the components for thermal insulation reinforcing elements.

The integrated in the components for thermal insulation shear bars are designed so that on the one hand, the angle of inclination of the transverse force bars to the smallest width or thickness, therefore the minimum thickness of the thermally insulating body, which ensures only the minimum heat protection, and the lowest height of the connected component is aligned and on the other hand, the inclination angle of the transverse force bars at a constant height and with increasing thickness of the thermally insulating body does not change. In order nevertheless to be able to anchor the transverse force rods securely in the adjacent components with increasing thickness of the thermally insulating body, the latter therefore has recesses in the region of the transverse force rods into which the concrete flows when installing the component for thermal insulation. These recesses are necessary to support the transition arc between the vertically inclined portion of the transverse force rod and the anchored in the adjacent components portion of the transverse force rod in the concrete of the adjacent components. However, the recesses are limited executable in their dimensions, which is why the known from the prior art components for thermal insulation, the transverse force rods preferably have a tilt angle of 45 degrees, only allow an insulation thickness of up to 12 centimeters. in the In contrast, in the case of low-energy houses, the typical thicknesses of the insulation of the external building wall are up to 30 centimeters. Due to the small dimensions of the thermally insulating body, the components known from the prior art for thermal insulation therefore form a thermal bridge in the installed state.

Furthermore, results from the design and elementation of integrated in the components for thermal insulation reinforcing elements over-dimensioning of the tensile bars, which increases with the increase in the number or proportion of lateral force rods and in the known components for thermal insulation, the transverse force rods preferably have an inclination angle of 45 degrees by up to 130 percent. If one were to reduce the angle of inclination of the transverse force rods in order to obtain thicker components for thermal insulation, this would further increase the degree of over-dimensioning of the tensile force rods. The known components for thermal insulation therefore only have, as already described, a width or thickness of at most 12 centimeters.

In addition, the tensile bars are so oversized that the connection reinforcement is adapted only to the number or proportion of Zugkraftstäbe for connecting the components for thermal insulation of the respective adjacent component. The number or the proportion of shear bars is not taken into account due to the over-dimensioning of the tensile bars.

Since the tensile bars consist of a material whose thermal insulating properties are substantially lower than those of the thermally insulating body they pass through, the over-dimensioning of the tensile bars results in an unnecessary deterioration of the thermally insulating function of the thermal insulation elements. It is therefore not surprising that the known embodiments of components for thermal insulation only have insufficient thermal protection.

Furthermore, the known components for thermal insulation on a very high weight, which is also due to the oversizing of Zugkraftstäbe and the associated high proportion of Zugkraftstäbe, resulting in an inadequate handling of the components during transport and on the site. In addition, the over-dimensioning of the tensile bars results in unnecessarily high production costs for the components for thermal insulation. Furthermore, from DE 102005039025 A1 a device for thermal insulation is known, which is designed to reduce the thermal bridge effect about 20 centimeters thick, wherein the device on the side of the supporting member has significant recesses for the transverse force rods, which extends to the top of the thermally insulating body extend. The large recesses on the one hand, the inclination angle of the transverse force rods of 45 degrees can be maintained and on the other hand, the proper filling of the recesses is guaranteed with in-situ concrete. However, these recesses themselves form significant thermal bridges in the thermal insulation component, so that only one thermal insulation component results, which has slightly improved thermal insulation properties. Due to the required large recesses for the transverse force rods also reduces the maximum number of tensile and transverse force rods to be integrated in the component for thermal insulation considerably, so that such a component for thermal insulation is not suitable for the transmission of all current loads.

Presentation of the invention

Proceeding from this, the present invention seeks to propose a component system for thermal insulation, the components for thermal insulation are optimally and economically tunable to today's typical thicknesses of building insulation and which are characterized by very good thermal insulation properties, so that the components of the component system for a variety of applications , in particular for use in passive houses, while at the same time a material and weight saving should be made, thereby facilitating the transport and to improve handling.

This object is achieved by a component system for thermal insulation with the features of independent claim 1.

The component system according to the invention for thermal insulation consists of components for thermal insulation, which have different dimensions and different reinforcement proportions, the proportion or the number of tensile bars of the respective component is designed and elemented for thermal insulation, that the design value of the absorbable tensile force of Zugkraftstäbe to measure the tensile force which can be introduced into the adjacent load-bearing component and which arises the design value of the absorbable tensile force of at least one transverse force rod and its inclination angle is smaller than the design value of the maximum acting compressive force on the pressure elements, resulting from the recordable loads of the component for thermal insulation.

Due to this elementation, the design value of the absorbable tensile force of the tensile bars is smaller than the tensile force which can be induced by the tensile and transverse force bars by the amount of tensile force which can be introduced into the adjacent structural component resulting from the design value of the absorbable tensile force of at least one transverse force rod and its inclination angle in the load-bearing component, which results from the aufnehmbareπ loads of the component for thermal insulation. As a result, the reinforcing elements are matched to one another so that an over-dimensioning of the tensile bars is largely avoided.

The slightest oversizing of the tensile bars and thus the most optimal elementation of the reinforcing elements results when the proportion and / or the number of tensile bars of the respective component is designed and elemented for thermal insulation so that the design value of the absorbable tensile force of Zugkraftstäbe to the extent of in the adjacent load-bearing component initiating tensile force, which results from the design value of the absorbable tensile force of the transverse force bars and the inclination angle of the transverse force bars, is smaller than the design value of the maximum acting compressive force on the pressure elements, resulting from the recordable loads of the component for thermal insulation. It concludes that the design value of the absorbable tensile force of the tensile bars is smaller than that of the tensile and tensile forces by the amount of tensile force which can be introduced into the adjacent structural element resulting from the design value of the absorbable tensile force of the transverse force bars and the angle of inclination of the transverse force bars Transverse force rods introduced tensile force in the load-bearing component, which results from the recordable loads of the component for thermal insulation.

The component system for thermal insulation consists of components for thermal insulation designed and elemented for different load cases and thus for different levels of stress. The components for thermal insulation are therefore divided into different load groups, which is characterized by the maximum absorbable load of the integrated reinforcing elements and their number or proportions. The load groups can be calculated according to the number or the proportion of tensile bars, according to the number or proportion of lateral force bars, after the Divide the number or proportion of the printing elements or a combination thereof. Most useful, however, is the structure of the load groups according to the number or proportion of tensile bars. Depending on the load group, the components for thermal insulation therefore have a fixed number or a fixed proportion of tensile bars, wherein the number or proportion of lateral force bars and the pressure elements within the load group is variable, whereby the device for thermal insulation optimally to the loads to be transmitted is tuned and over-dimensioning of the reinforcing elements, in particular the tensile bars, is largely avoided. As a result of this arrangement, the proportion and / or the number of printing elements changes with the change in the proportion and / or the number of transverse force rods when the proportion and / or number of tensile force bars is substantially the same.

Since the tensile and transverse force rods are now optimally utilized, it is necessary that for the connection of the components for thermal insulation of the respective adjacent component, the tensile and transverse force bars are matched with the connection reinforcement, the tensile and transverse force rods with the in the respective adjacent component integrated connection reinforcement are directly in operative connection. This operative connection is ensured in its simplest form by a lap joint. The tensile and transverse force rods therefore extend so far into the adjacent component until they overlap with the connection reinforcement of the adjacent component. For better tensile force transmission, the connection reinforcement is in the same plane as the tensile and transverse force rods, so that a so-called one-level impact is formed. Of course, the tensile and transverse force rods can also be used with other anchoring variants known from the prior art, e.g. with socket joints, anchored in the adjacent components.

By designing and elementing the reinforcement elements contained in the thermal insulation components, it is also possible to vary the number or proportion of lateral force rods and their inclination angle, without this having an effect on the degree of utilization of Zugkraftstäbe. The angle of inclination of the transverse force rods depends on the connection points with the reinforcement integrated in the adjacent components as well as the width or thickness and the height of the thermally insulating body of the component installed between the two components, the height of the thermally insulating body again depending on the Height of one of the adjacent components. In order to achieve optimum coordination of the transverse force rods, it is expedient that the angle of inclination of the transverse force rods not only at a constant width or thickness and decreasing height of the thermally insulating body but also at a constant height and decreases with increasing thickness of the thermally insulating body. The angle of inclination preferably varies between 15 degrees and 60 degrees, in particular less than or equal to 45 degrees.

In order to reduce thermal bridges in the connection area of components for thermal insulation to a minimum, it is expedient that the thermally insulating body of the respective component for thermal insulation substantially corresponds to the thickness of the insulation of the building exterior wall. The thermally insulating body, which is part of each component system for thermal insulation, are therefore variable not only in their height and length but also in their width or thickness, so that they are optimally adapted to the given geometric installation conditions on the one hand and on the other hand executed can essentially correspond to the thickness of the insulation of the building exterior wall. The thermal bridge is the smaller, the more the thickness of the thermally insulating body of the thermal insulation component equalizes the thickness of the insulation of the building exterior wall. The component system for thermal insulation therefore has components for thermal insulation, the thermally insulating body essentially correspond to the typical today thicknesses of building insulation, therefore preferably between 8 to 30 centimeters, wherein the gradation of the thickness of the thermally insulating body is approximately between 2 to 8 centimeters, in particular about 2 to 4 inches, can be.

Since the angle of inclination of the transverse force rods at a constant height and decreases with increasing thickness of the thermally insulating body, the component system for thermal insulation may also have components for thermal insulation, the thermally insulating body in vertical section in about the same width or thickness as high and on the other hand, wider or thicker is how high, wherein the angle of inclination of the transverse force rods in these components can be below 45 degrees for thermal insulation.

As far as the shape and the choice of material of the transverse force rods is concerned, it is advisable to carry them out like the transverse force rods known from the prior art. The transverse force bars may therefore consist of stainless steel, structural / reinforcing steel, fiber reinforced plastic or other suitable material, as well as sections of various materials joined together by, for example, welded, threaded or socket joints, the transverse force bars being round, rectangular or otherwise convenient Cross section may have. In order to keep the number of transverse force bars with different angles of inclination low, there is an expedient development of the component system is that the different thickness thermally insulating body are combined in groups of two thermally insulating bodies and that within each group of the second thermally insulating body recesses on the Having input or output points of the transverse force rods with the thermally insulating body, so that each have two thermally insulating body of different thickness, therefore, a thermally insulating body without recesses and a thicker thermally insulating body with recesses, transverse force rods with the same inclination angle. Since the component system consists of several groups which in turn have different thicknesses of thermally insulating body, changes in height and with increasing thickness of the thermally insulating body and with the group of inclination angle of the transverse force rods. The shape of the recesses can be carried out according to the prior art.

A particularly expedient development of the component system is that the differently thick thermally insulating bodies are combined in groups of three thermally insulating bodies and that within each group of the second thermally insulating body recesses at the entry or exit points of the transverse force rods with the thermally insulating body and that the third thermally insulating body has recesses at the entry and exit points of the transverse force bars with the thermally insulating body, so that in each case three thermally insulating body of different thickness, therefore a thermally insulating body without recesses, a thicker thermally insulating body with recesses on a Side of the thermally insulating body and a still thicker thermally insulating body with recesses on both sides of the thermally insulating body, transverse force rods with the same inclination angle isen. Since the component system consists of several groups which in turn have different thicknesses of thermally insulating body, changes in height and with increasing thickness of the thermally insulating body and with the group of inclination angle of the transverse force rods. The shape of the recesses can also be carried out according to the prior art.

The preceding description of the group formation of several components not only reduces the number of transverse force rods, but also the number of truss systems to be dimensioned, which simplifies the design tables, according to which, for example, the structural engineer determines the component for thermal insulation. As far as the shape and the choice of material of the tensile bars is concerned, it is advisable to carry them out like the tensile bars known from the prior art. The tensile bars can therefore be made of stainless steel, structural / reinforcing steel, fiber reinforced plastic or other suitable material, as well as sections of various materials joined together by, for example, welded, threaded or socket joints, the tension bars being round, rectangular or otherwise convenient Cross section may have.

As far as the shape and the choice of material of the printing elements are concerned, it is advisable to carry them out like the printing elements known from the prior art. The pressure elements may therefore be made of stainless steel, structural / reinforcing steel, fiber reinforced plastic, concrete or other suitable material as well as parts of different materials, which are interconnected by, for example, adhesive, welding, screw or socket joints, the pressure elements a round , rectangular or other appropriate cross section may have. As regards the particularly preferred embodiment of the printing elements, which are ideally suited for such a thermal insulation component system, the same applicant should be referred to the patent application "Thermal insulation component" filed on the same date, in which a multi-part pressure element is described in order to avoid repetition referenced, to which reference is made in full content.

The pressure elements are preferably to be designed such that they have a greater extent transversely to the longitudinal extent of the thermally insulating body than in the longitudinal extent of the thermally insulating body. As a result, on the one hand, the pressure elements can be adapted particularly advantageously to the different thicknesses of the thermally insulating body and, on the other hand, optimum coordination or elementing on the other reinforcing elements is thus possible.

Since, in addition, the angle of inclination of the transverse force rods decreases at the same height and with increasing thickness of the thermally insulating body, the component system for thermal insulation can therefore also have components for thermal insulation whose pressure elements have a greater extent transversely to the longitudinal extent of the thermally insulating body than in the longitudinal extent of the thermally insulating body, wherein the angle of inclination of the transverse force bars may be below 45 degrees in these components for thermal insulation.

In order to be able to transfer the loads occurring by the supported component safely into the supporting component, which should be through the thermally insulating body extending reinforcing elements adapt to the changed dimensions of the thermally insulating body. Since the angle of inclination of the transverse force rods decreases at a constant height and with increasing thickness of the thermally insulating body, increases the load acting on the reinforcing elements, with constant load by the supported component. It is therefore expedient that with substantially constant permissible load capacity of the different thickness components for thermal insulation, with decreasing inclination angle of the transverse force rods and increasing thickness of the thermally insulating body, the number or proportion of transverse force transmitted reinforcement elements, which the respective thermal traverse insulating body, increased.

In addition, it is expedient to match the reinforcing elements of the component system for thermal insulation, therefore, to element, and to measure the reinforcing elements so that the undesirable deformation of the framework formed by the reinforcing elements with decreasing inclination angle of the transverse force rods and with increasing thickness of the thermally insulating body remains essentially the same or increases only slightly.

Since at a constant height and with increasing thickness of the thermally insulating body increases the length of the extending through the thermally insulating body portion of the transverse force rods, it is therefore advisable to measure the transverse force rods so that with decreasing inclination angle of the transverse force rods and increasing thickness of the thermally insulating body reduces the stress on the transverse force rods. As a result, excessive stretching and thus change in length of the extending through the thermally insulating body portion of the transverse force rods is prevented.

For the same purpose, it is also advisable to dimension the tensile bars so that the load of the tensile bars is reduced with decreasing angle of inclination of the transverse force bars and with increasing thickness of the thermally insulating body.

Since the reduction of the stress of the tensile bars also reduces the necessary bond length of the tensile bars in the adjacent components, there is an expedient development of the component system is that with decreasing inclination angle of the transverse force bars and with increasing thickness of the thermally insulating body, the length of the Zugkraftstäbe same diameter remains essentially the same. In addition, this results in the advantage that only tensile bars are the same for the different thickness components for thermal insulation Diameter with a length needed and stockpiled. As a result, on the one hand reduces the number of parts of the entire component system for thermal insulation and on the other hand, fewer errors can occur during assembly of the device for thermal insulation.

The traction rods preferably each consist of three along a common axis successively arranged sections, which are preferably welded together. The middle section is preferably made of ribbed stainless steel. The adjoining the middle section on both sides sections are preferably made of ribbed construction / reinforcing steel. The respective traction rod is arranged in the thermally insulating body so that the central portion completely passes through the thermally insulating body, projects on both sides of the thermally insulating body and in the installed state of the components in the adjacent components binds. Since with decreasing inclination angle of the transverse force rods and with increasing thickness of the thermally insulating body, the length of Zugkraftstäbe same diameter remains substantially the same and the Zugkraftstäbe preferably have a same configuration, decreases with decreasing inclination angle of the transverse force bars and with increasing thickness of the thermally insulating body the insertion length of the middle section of the tensile bars.

Furthermore, it is advisable to dimension the pressure elements so that with decreasing inclination angle of the transverse force bars and with increasing thickness of the thermally insulating body, the deformation of the pressure elements remains substantially the same. The pressure elements are therefore so rigid perform that increases with decreasing inclination angle of the transverse force rods and with increasing thickness of the thermally insulating body only their length. The high bending stiffness of the pressure elements is necessary in order to keep the angle of rotation of the framework, which results from the elongation of the individual reinforcing elements and its elastic and plastic deformations, as low as possible. The rigid elongated pressure elements allow on the one hand optimal coordination of the pressure elements on the tensile and / or transverse force rods and on the other hand, the number of parts of the entire component system for thermal insulation is kept low.

The thermally insulating body of the components of the component system consists of at least one heat-insulating material, preferably expanded or extruded plastics, for example polyurethane, polyisocyanurate, phenolic resin or polystyrene, which are optionally mixed with graphite and / or elasticized, Mineral foam, foam glass, mineral wool, especially glass or rock wool, or other suitable material, which may also be sound-absorbing material and / or fire protection material. The material used for the thermally insulating body preferably has a bulk density of at least 10 kilograms / cubic meter, in particular at least 30 kilograms / cubic meter, and a thermal conductivity of less than 0.045 watts / (meters x Kelvin), in particular less than 0.025 watts / (meters x Kelvin) , on.

The present invention has the advantage that the number or proportion of reinforcing elements in the components for thermal insulation of the component system for thermal insulation is reduced to the necessary level, which is why the material requirements for the reinforcing elements, compared to the prior art, considerably reduced. Since the reinforcing elements consist of a material whose thermal insulating properties are substantially lower than those of the thermally insulating body they pass through, the reduction of the material requirement for the reinforcing elements results in an improvement of the thermally insulating function of the respective component for thermal insulation, so that the respective component for thermal insulation for use in Niedrigstenergiehäusern, in particular passive houses, is suitable. In addition, the material savings for a cost savings and a lower weight of the components for thermal insulation, which facilitates their transport and improves handling.

By means of the component system for thermal insulation described here, it is also made possible for the first time optimally and economically tune components for thermal insulation on today's typical thicknesses of the insulation of a building exterior wall, since the number or proportion of lateral force rods and their inclination angle can vary without affecting this has the degree of utilization of tensile bars.

Of course, with the component system for thermal insulation, if it is adapted to the purpose, also supported components made of reinforced concrete, such as attics, parapets, canopies, cantilevers and / or wall panels, to load-bearing structural elements made of reinforced concrete, such as ceiling panels and / or wall panels, are connected. In the following, some embodiments of the present invention will be illustrated with reference to drawings and explained in more detail.

Show it:

Figure 1: a first embodiment of a component system for

Thermal insulation in a schematic vertical section;

Figure 2: a second embodiment of a component system for

Thermal insulation in a schematic vertical section; and

Figure 3: a third embodiment of a component system for

Thermal insulation in a schematic vertical section.

It should be noted that the component system for thermal insulation is shown only schematically in the figures shown. The component system for thermal insulation is therefore not provided with all its components, such as Cover or any fire protection element, and with all its known from the prior art embodiments, which relates to the different design of the reinforcing elements in the thermally insulating body, shown, since they have nothing to do with the present invention and are prior art. Furthermore, it was forgiven to map the components for thermal insulation in all their well-known from the prior art heights and adjacent to the thermally insulating body concrete components, which are usually the same height from the thermally insulating body, starting to the right or to the left (related to Figures 1 to 3), as this is not necessary for the presentation of the present invention.

FIG. 1 shows a first embodiment of a component system for thermal insulation in a schematic vertical section. The components of the component system consist essentially of a thermally insulating body 2a-2l and of reinforcing elements in the form of tensile bars 3a-3l and transverse force bars 4a-4l and pressure elements 5a-5l. The tensile force bars 3a-3l and the pressure elements 5a-5l penetrate the thermally insulating bodies 2a-2l substantially horizontally. The transverse force rods 4a-4l penetrate the thermally insulating bodies 2a-2l obliquely, therefore inclined in the vertical. The thermally insulating bodies 2a-2l have approximately planar side edges 6a-6l and 7a-7l. The inclination angle α _a -αι of the transverse force rods 4 _a- 4 I decreases with increasing thickness of the thermally insulating body 2 a-2 l. Everyone thermally insulating body 2a-2l therefore has transverse force rods whose inclination is adapted to the respective thickness of the thermally insulating body and which differ by their respective inclination angle α _a - αι.

FIG. 2 shows a second embodiment of a component system for thermal insulation in a schematic vertical section. The essential difference from the thermal insulation component system of FIG. 1 is that the differently thick thermally insulating bodies 12a-12l are arranged in groups of two thermally insulating bodies 12a, 12b; 12c, 12d; 12e, 12f; 12g, 12h; 12i, 12j, 12k, 121, and that within each group the second thermally insulating body, hence the thermally insulating bodies 12b, 12d, 12f, 12h, 12j, 12l, are approximately planar side edges 16b, 16d, 16f, 16h, 16j , 16l and side edges 17b, 17d, 17f, 17h, 17j, 17I, in which recesses 18b, 18d, 18f, 18h, 18j, 18l at the entry and exit points of the transverse force bars 14ab, 14cd, 14ef, 14gh, 14ij , 14kl with the thermally insulating bodies 12b, 12d, 12f, 12rt, 12j, 12l, into which the concrete flows when installing the respective component for thermal insulation. Thus, there are always two thermally insulating bodies, therefore 12a and 12b, 12c and 12d, 12e and 12f, 12g and 12h, 12i and 12j, 12k and 121, having the same transverse force bars, hence 14ab, 14cd, 14ef, 14gh, 14ij and 14kl , with their associated angles of inclination .alpha..sub.a _b .αc _d .α _{ef gh} .α .αj .α _{k j} i on. The lateral force bars 14ab, 14cd, 14ef, 14gh, 14ij, 14kl are distinguished by their inclination angle ciab, cicd.c (ef, αg _h .ciij _> c (ki), which decreases with increasing thickness of the thermally insulating bodies 12a to 121, therefore α _ab <α _Cd <α e _f ^< α _{h h} <αr _J <α _k |.

FIG. 3 shows a third embodiment of a component system for thermal insulation in a schematic vertical section. The essential difference from the thermal insulation component system of FIGS. 1 and 2 is that the differently thick thermally insulating bodies 22a-22l are arranged in groups of three thermally insulating bodies 22a, 22b, 22c; 22d, 22e, 22f; 22g, 22h, 22i; 22j, 22k, 22l and that within each group the second thermally insulating body, hence the thermally insulating bodies 22b, 22e, 22h, 22k, are approximately planar side edges 26b, 26e, 26h, 26k, and side edges 27b, 27e, 27h , 27k, in which recesses 28b, 28e, 28h, 28k are located at the entry and exit points of the transverse force bars 24abc, 24def, 24ghi, 24jkl with the thermally insulating bodies 22b, 22e, 22h, 22k, and that the third is thermal insulating bodies, therefore, the thermally insulating bodies 22c, 22f, 22i, 22l, side edges 26c, 27c; 26f, 27f; 26i, 27i; 261, 271, in which recesses 28c, 29c; 28f, 29f; 28i, 29i; 281,291 at the entry and exit points of the transverse force rods 24abc, 24def, 24ghi, 24jkl with the thermal insulating bodies 22c, 22f, 22i, 22l are located. Therefore, there are always three thermally insulating bodies, therefore 22a, 22b, 22c; 22d, 22e, 22f; 22g, 22h, 22i; and 22j, 22k, 12l, the same lateral force bars, hence 24abc, 24def, 24ghi, and 24jkl, with their associated inclination angles α _a b _C , αde _f .αg _h i _> c ( _jk i) The lateral force bars 24abc, 24def, 24ghi, 24jkl differ by their inclination angle α _abC , α _def , αg _h i, α _jk i, which decreases with increasing thickness of the thermally insulating bodies 22a to 221, therefore αa _b c ^ dβ ^ αg _h ^ αju.

Claims

claims

1. component system for thermal insulation, consisting of components for thermal insulation of different dimensions, wherein the components for thermal insulation between two components to be concreted, in particular between a supported component and a load-bearing component of a building, are installed and each at least from a thermally insulating body to be arranged therebetween ( 2a-2l; 12a-12l; 22a-22l) with integrated pressure elements (5a-5l; 15a-151; 25a-25l), tensile bars (3a-3l; 13a-13l; 23a-23l) and transverse force bars (4a-4l; 14ab-14kl; 24abc-24jkl) which pass through the thermally insulating body (2a-2l; 12a-12l; 22a-22I) and are respectively connectable to both components, the components being thermally insulated for different load cases by the element Proportion and / or the number of reinforcing elements in the components for thermal insulation varies, characterized in that the inclination angle (α _a -αf, α _ab -α _M α _abc -α _jk i) of the lateral force rods (4a-4l; 14ab-14kl; 24abc-24jkl) at substantially constant height and with increasing thickness of the thermally insulating bodies (2a-2l; 12a-12l; 22a-22I), wherein the proportion and / or the number of traction rods (3a-3l; 13l, 23a-23l) of the respective component for thermal insulation is designed and elemented so that the rated value of the absorbable tensile force of the tensile force rods (3a-3l; 13a-131; 23a-23l) can be introduced by the amount of tensile force that can be introduced into the adjacent supporting component, which results from the design value of the absorbable tensile force of at least one transverse force rod (4a-4l; 14ab-14kl; 24abc-24jkl) and its inclination angle (α _a -αι; α _ab -α _k r, αabc-αjki) is smaller than that Design value of the maximum compressive force acting on the pressure elements (5a-5l; 15a-15l; 25a-25l) resulting from the absorbable loads of the thermal insulation component.

2. The component according to claim 1, characterized in that the design value of the absorbable tensile force of the tensile force rods (3a-3l; 13a-13l; 23a-23l) by the extent of the tensile load, which can be introduced into the adjacent bearing component, resulting from the design value of the receivable tensile force of at least one transverse force bar (4a-4l; 14ab-14kl; 24abc-24jkl) and its angle of inclination (α _a -αι; α _a b-α _k ι; α _abc -αjκι) yields, is less than that (of the tensile bars 3a -3l; 13a-13l; 23a-23l) and transverse force rods (4a-4l; 14ab-14kl; 24abc-24jkl) Tensile force in the load-bearing component, which results from the absorbable loads of the component for thermal insulation.

3. The component according to one of the preceding claims, characterized in that the proportion and / or the number of tensile bars (3a-3l; 13a-13l; 23a-23l) of the respective component for thermal insulation is designed and elemented so that the rated value of the 13a-13l; 23a-23l) by the amount of tensile force which can be introduced into the adjacent supporting component, which is calculated from the design value of the absorbable tensile force of the transverse force rods (4a-4l; 14ab-14kl; 24abc). 24jkl) and the angle of inclination (α _a -αι; α _ab -α _k ι; da _bc -oi _jk i) gives the lateral force bars, is smaller than the design value of the maximum compressive force acting on the pressure elements (5a-5l, 15a-15l; 25a-25l), which results from the recordable loads of the component for thermal insulation.

4. The component according to one of the preceding claims, characterized in that the design value of the absorbable tensile force of the tensile force rods (3a-3l; 13a-13l; 23a-23l) by the extent of the tensile load, which can be introduced into the adjacent bearing component, resulting from the design value of recordable tensile force of the transverse-force bars (4a-4l; 14ab-14kl; 24abc-24jkl) and the angle of inclination (α _a - oii; α _from -α _w; α _abc -α _jk i) of the transverse-force bars (4a-4l; 14ab-14kl 24abc-24jkl) is smaller than the tensile force that can be induced by the tensile bars (3a-3l; 13a-13l; 23a-23l) and the transverse bars (4a-4l; 14ab-14kl; 24abc-24jkl) into the load-bearing member resulting from the recordable loads of the device for thermal insulation.

5. Component according to one of the preceding claims, characterized in that at substantially constant proportion and / or number of tensile bars (3a-3l; 13a-13l; 23a-23l) with the change in the proportion and / or the number of Transverse force rods (4a-4l; 14ab-14kl; 24abc-24jkl) the proportion and / or the number of pressure elements (5a-5l; 15a-15l; 25a-25l) changes.

6. The component according to one of the preceding claims, characterized in that the tensile force rods (3a-3l; 13a-13l; 23a-23l) and transverse force rods (4a-4l; 14ab-14kl; 24abc-24jkl) by an overlapping joint with the connection reinforcement in anchored adjacent component.

7. The component according to any one of the preceding claims, characterized in that the transverse-force bars (4a-4l; 14ab-14kl; 24abc-24jkl) in the installed state an angle of inclination (α _A -α _{(α from} -α _k ι; α _abc - α _jk |) compared to the Horizontal plane of between 15 degrees and 60 degrees, in particular less than or equal to 45 degrees.

8. The component according to one of the preceding claims, characterized in that the thermally insulating body (2a-2l; 12a-12l; 22a-22l) are preferably between 8 to 30 centimeters thick, wherein the gradation of the thickness of the thermally insulating body (2a -2l, 12a-12l, 22a-22l) is between about 2 to 8 centimeters, in particular about 2 to 4 centimeters.

9. The component according to one of the preceding claims, characterized in that the component system for thermal insulation components for thermal insulation, the thermally insulating body in vertical section in about the same width or thickness as high and the other is wider or thicker as high wherein the angle of inclination of the transverse force transmitting reinforcing elements in these thermal insulation components may be less than 45 degrees.

10. The component according to one of the preceding claims, characterized in that the differently thick thermally insulating bodies (12a-12l) in groups of two thermally insulating bodies (12a, 12b; 12c, 12d; 12e, 12f; 12g, 12h; , 12j, 12k, 121) and that within each group the second thermally insulating body (12b, 12d, 12f, 12h, 12j, 12l) recesses (18b, 18d, 18f, 18h, 18j, 18l) to the input or two thermally insulating bodies of different thicknesses (12a, 12b, 12c, 12d, 12e, 12f, 12g, 12h, 12i, 12j, 12k, 12l), thus a thermally insulating body without recesses (12a, 12c, 12e, 12g, 12i, 12k) and a thicker thermally insulating body (12b, 12d, 12f, 12h, 12j, 12l) with recesses (18b, 18d, 18f, 18h, 18j, 18l), transverse force rods (14ab, 14cd, 14ef, 14gh, 14ij, 14kl) with the same angle of inclination (α _.beta.f, α _gh, α ^ α _k, α _at>, α ^) have.

11. The component according to claim 1 to 9, characterized in that the different thickness thermally insulating bodies (22a-22l) in groups of three thermally insulating bodies (22a, 22b, 22c, 22d, 22e, 22f, 22g, 22h, 22i 22j, 22k, 22l) and that within each group the second thermally insulating body (22b, 22e, 22h, 22k) has recesses (28b, 28e, 28h, 28k) at the entry or exit points of the lateral force rods (24abc, 24def , 24ghi, 24 \ k \) with the thermally insulating body (22b, 22e, 22h, 22k), and the third thermally insulating body (22c, 22f, 22i, 22l) has recesses (28c, 29c, 28f, 29f; 28i, 29i; 281, 291) at the entry and exit points of the transverse force rods (24abc, 24def, 24ghi, 24jkl) with the thermally insulating body (22c, 22f, 22i, 22l), so that in each case three thermally insulating bodies of different thicknesses (22a, 22b, 22c; 22d, 22e, 22f, 22g, 22h, 22i, 22j, 22k, 22l), therefore a thermally insulating body without recesses (22a, 22d, 22g, 22j), a thicker thermally insulating body (22b, 22e, 22h, 22k) with recesses (28b, 28e, 28h, 28k) on one side of the thermally insulating body (22b, 22e, 22h, 22k) and a further thicker thermally insulating body (22c, 22f, 22i, 22l) with recesses (28c, 29c; 28f, 29f, 28i, 29i, 281, 291) on both sides of the thermally insulating body, transverse force rods (24abc, 24def, 24ghi, 24jkl) with the same inclination angle (α _a bc _> α _de f, α _g hi, otjki).

12. The component according to one of the preceding claims, characterized in that the pressure elements (5a-5l; 15a-15l; 25a-25l) transverse to the longitudinal extent of the thermally insulating body (2a-2l; 12a-12l; 22a-22l) a larger Have extension than in the longitudinal extent of the thermally insulating body.

13. The component according to claim 12, characterized in that the component system for thermal insulation components for thermal insulation, the pressure elements transversely to the longitudinal extent of the thermally insulating body have a greater extent than in the longitudinal extent of the thermally insulating body, wherein the inclination angle of the transverse force rods in these components for thermal insulation may be below 45 degrees.

14. Component according to one of the preceding claims, characterized in that with decreasing inclination angle (α _a -αι; α _ab -α _k ι; α _abc - α _jk ι) of the transverse force rods (4a-4l; 14ab-14kl; 24abc 24jkl) and with increasing thickness of the thermally insulating bodies (2a-2l; 12a-12l; 22a-22l), the length of the traction rods (3a-13i; 13a-13l; 23a-23l) of the same diameter remains essentially the same.

15. Component according to one of the preceding claims, characterized in that with decreasing inclination angle (α _a -αι; α _ab -α _k ι; α _abc - (Xj _W ) of the transverse force rods (4a-4l; 14ab-14kl; 24abc 24jkl) and with increasing thickness of the thermally insulating bodies (2a-2l; 12a-12l; 22a-22l) the length of the pressure elements (5a-5I; 15a-15l; 25a-25l) increases.