DE102007014926A1 - Elementization of a component system for thermal insulation - Google Patents

Abstract

In the known component systems for thermal insulation, the components for thermal insulation inadequate elementation of the integrated reinforcing elements, therefore the tension rods, the transverse force rods and the pressure elements, on. This results in an over-dimensioning of the tension rods, which increases with the increase in the number or proportion of lateral force rods. Since the tie rods are made of a material whose thermal insulating properties are substantially lower than those of the thermally insulating body that they enforce, over-sizing of the tie rods results in an unnecessary deterioration of the thermal insulating function of the thermal insulation components. The components for thermal insulation therefore have only an insufficient thermal protection, which often just barely meets the minimum heat protection and thus should only prevent structural damage. Due to the poor thermal insulation properties of the components, these therefore form heat or cold bridges even when installed, which should be reduced to a minimum by the use of the components for thermal insulation in the field of use. The individual components for thermal insulation of the new component system for thermal insulation should, due to the advantageous elementation of the reinforcing elements, characterized by very good thermal insulation properties, so that the components of the component system are suitable for use in passive houses, at the same time a material and ...

Description

field of use

The The invention relates to a component system for thermal insulation, consisting of components for Thermal insulation, taking the components for thermal insulation between two components to be concreted, in particular between a supported component and a load-bearing component, being built in and out of one in between to be arranged thermally insulating body with at least integrated pressure elements, wherein the pressure elements used in the components for thermal insulation and component of the components are, and integrable train and Transverse force bars exist, which are transverse to the longitudinal extent of the thermally insulating body run through it and can be connected to both components, the lateral force rods in mutually parallel vertical planes the thermally insulating body traversed inclined, the components for thermal insulation for different load cases are by the proportion and / or the number of reinforcement elements varies in the components for thermal insulation.

State of the art

component systems for thermal insulation are in the relevant Prior art known in many different versions. With you Two components become thermo-technical decoupled from each other to or cold bridge in this area but at the same time statically connected with each other. This static connection takes place via reinforcing elements, therefore Tension rods, shear force rods and pressure elements, which extend through a thermally insulating body, generally insulating body and incorporate it into the adjacent components. Transfer the reinforcement elements while the loads caused by the supported component, Therefore, in particular tensile, compressive and shear forces on the supporting component. The known component systems for thermal insulation consist of components for thermal insulation, the different dimensions and different reinforcement proportions exhibit. Define the reinforcement parts of the reinforcement elements through their length and their circumference, hence by their volume, and by their number. Since the loads caused by the supported component on the device for thermal insulation depending on embodiment change the supported component, vary the for the transfer the loads necessary proportions of the reinforcing elements. The Component systems exist for thermal insulation Therefore, from components for thermal insulation for different loading cases and for that different loads are designed and elemented. The components for thermal insulation are for in subdivided into different load groups, extending through the maximum Recordable load of the integrated reinforcement elements and their Number or proportions. Depending on the load group point the components therefore a defined number or proportion of tension rods, shear bars and Pressure elements, wherein the number or proportion of the transverse force rods within the loading group is variable, since the reinforcing elements of the Components for thermal insulation so are designed and elemented that the rated value of the recordable Tensile force of the tension rods essentially the rated value of the compressive force of the Corresponds to printing elements or, in the case of strongly over-sized printing elements, that the design value of the absorbable tensile force of the tension rods is the rated value corresponds to the maximum acting compressive force on the printing elements, which results from the recordable loads of the component for thermal insulation. However, this results in an overestimation the tension rods, with the increase of Number or proportion of lateral force rods increases and in the known Building elements for thermal insulation whose Shear bars preferably have an inclination angle of 45 degrees, up to 130% is. Would you reduce the angle of inclination of the transverse force rods to thicker components for Thermal insulation too received, so would This increases the degree of oversizing the tension rods on increase. The known components for thermal insulation have therefore only a maximum thickness of 12 cm. Furthermore, the Tension rods overemphasized, that for the connection of the components for thermal insulation at the respective adjacent Component the required connection reinforcement only to the number or the proportion of tension rods is agreed. The number or proportion of lateral force rods is due to the oversizing the tension rods not taken into account. Component systems of this kind are, for example, from the companies Schöck, Halfen, H-Bau and Egco known.

Since the tie rods are made of a material whose thermal insulating properties are substantially lower than those of the thermally insulating body that they enforce, over-sizing of the tie rods results in an unnecessary deterioration of the thermal insulating function of the thermal insulation components. It is therefore not surprising that the known embodiments of components for thermal insulation only have insufficient thermal protection, which often just barely meets the minimum heat protection and thus should only prevent structural damage. Due to the poor thermal insulation properties of the known components, these therefore form even when installed heat Me- or cold bridges, which should be reduced just by the use of the components for thermal insulation in the field to a minimum. There is therefore no sufficient thermal separation between the outer and inner components or between the supported and the supporting components.

There Thermal bridges in the energy balance of a building, especially in low energy houses Need to become The resulting energy losses by Mehrdämmung others Building parts are compensated. The resulting additional effort elevated the construction costs and deteriorate the economy of the building, why especially in the construction of Niedrigstenergiehäusern, especially passive houses, components for thermal insulation almost find no application. In addition, resulting from the insufficient increased thermal separation Energy losses, which on the one hand increased heating costs and on the other an increased climate damaging Carbon dioxide emissions to Episode has.

Farther The known components for thermal insulation have a very high weight on, which also on the over-dimensioning the tension rods and the associated high proportion of the tension rods, resulting in an insufficient Handling of the components during of transport and on the construction site results. In addition, are with over-dimensioning the tension rods unnecessary costs connected.

Object of the invention

Of these, The present invention is therefore based on the object to propose a component system for thermal insulation, whose Components for thermal insulation through very good thermal insulation properties so that the component is suitable for use in passive houses, at the same time a material and weight saving made to facilitate transport and handling to improve. Despite this, it should be inexpensive to manufacture.

Solution of the task

These Task is inventively characterized solved, that the proportion and / or the number of tension rods of the respective component for thermal insulation so designed and elemented is that the rated value of the recordable Tensile force of the tension rods the measure of tensile force which can be introduced into the adjacent load-bearing component and which from the design value of the absorbable tensile force at least one Transverse force bar and its angle of inclination is less than the rated value of the maximum compressive force acting on the pressure elements, which results from the absorbable loads of the component for thermal insulation, the components for thermal insulation in Stress groups are structured and being within a stress group at substantially constant proportion and / or number of tension rods with the change the proportion and / or the number of shear bars the share and / or the Number of printing elements changes or being within a stress group at substantially the same remaining proportion and / or number of printing elements with the change the proportion and / or the number of shear bars the share and / or the Number of tie rods changes.

Presentation of the invention

by virtue of This elementation is the design value of the absorbable tensile force the tension rods the measure of tensile force which can be introduced into the adjacent load-bearing component and which from the design value of the absorbable tensile force at least one Transverse force bar and its angle of inclination is smaller than that from the tensile and shear force bars Introducible tensile force in the bearing component, resulting from the receivable Loads of the component for thermal insulation results.

Thereby the reinforcing elements are adjusted to each other so that overstatement the tension rods is largely avoided.

The least oversizing the tension rods and so that the most optimal elementation of the reinforcing elements results itself, if the proportion and / or the number of tension rods of the respective Component for thermal insulation so designed and elemented is that the rated value of the recordable Tensile force of the tension rods the measure of tensile force which can be introduced into the adjacent load-bearing component and which from the design value of the absorbable tensile force of the transverse force rods and the Inclination angle of the transverse force rods is less than the design value of the maximum effect Pressure force on the pressure elements resulting from the absorbable Loads of the component for thermal insulation results. This concludes that the design value of the absorbable tensile force of the tension rods around the Measure of tensile force which can be introduced into the adjacent load-bearing component and which from the design value of the absorbable tensile force of the transverse force rods and the Inclination angle of the transverse force rods is smaller than that introduced by the tensile and transverse force bars Traction in the bearing component, resulting from the absorbable Loads of the component for thermal insulation results.

The component system for thermal insulation mung consists of components for thermal insulation which are 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 divided according to the number or the proportion of tension rods, the number or proportion of shear force rods, the number or proportion of pressure elements or a combination thereof. Most useful, however, is the classification of the load groups according to the number or proportion of tension rods or the number or proportion of pressure elements.

He follows the breakdown of the exposure groups according to the number or proportion the tension rods, then have the components for thermal insulation within a load group a fixed number or a fixed proportion on tension rods on, wherein the number or the proportion of the transverse force bars and the pressure elements within the load group is variable, causing the device optimal for thermal insulation to be transferred to Loads can be adjusted and over-dimensioning of the reinforcement elements, especially the tension rods, is largely avoided. This structure results in that at substantially the same proportion and / or number on tension rods with the change the proportion and / or the number of shear bars the share and / or the Number of printing elements changes.

If the breakdown of the exposure groups according to the number or proportion the printing elements is done, then the components for thermal insulation within a load group a fixed number or a fixed proportion on pressure elements, wherein the number or proportion of the transverse force rods and the Tension rods is variable within the load group. Thus, an overstatement the reinforcing elements largely avoided. Through this outline shows that at substantially the same proportion and / or number on printing elements with the change of Proportion and / or the number of lateral force rods, the proportion and / or the Number of tie rods changes.

There the tensile and shear force rods now be optimally utilized, it is necessary for the connection the components for thermal insulation of the each adjacent component, the tensile and transverse force bars with the Connection reinforcement are matched, the train and Shear bars with the connection reinforcement integrated in the respective adjacent component directly in operative connection. This active compound is in their simplest form ensured by a lap joint. The tensile and shear 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 forms a so-called one-level impact. Of course you can one the tensile and transverse force rods also with other anchoring variants known from the prior art, such as B. with socket joints, in anchor the adjacent components.

by virtue of the advantageous elementation of the reinforcing elements in the components reduced for thermal insulation the number or the proportion of reinforcing elements to the necessary extent, why the material requirement for the reinforcing elements, compared to the prior art, strong reduced. Since the reinforcing elements are made of one material, its thermally insulating properties significantly lower than those of the thermally insulating body they enforce, results from the reduction of material requirements for the reinforcement elements an improvement of the thermally insulating function of the components for thermal insulation. In addition, ensures the material savings for a cost saving and a lower weight of the components for thermal insulation, thereby facilitate their transport and improves handling.

By the advantageous elementation of reinforcing elements described here in the components for thermal insulation is the heat transfer coefficient of the components for thermal insulation so low, that it is economically possible, balcony constructions in the growth market of low-energy houses (houses in 3 liter house construction, Passive houses) directly to the building to join and not as before the balcony construction with columns in front to set the building. this leads to a reduction in the cost of the balcony construction and improves the planning freedom of the architect.

Description of exemplary embodiments

One embodiment and further features of the invention are shown in the drawing and will be closer in the following described.

It shew:

1 : a device for thermal insulation of a component system for thermal insulation in a schematic perspective view.

It should be noted that the device for Thermal insulation in the pictured 1 is shown only schematically. The device for thermal insulation is therefore not with all its parts, such. B. cover or any fire protection element, as well as 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 as they have nothing to do with the present invention and are prior art. Furthermore, it was waived to map the components for thermal insulation in all their also known from the prior art heights and thicknesses, as this is not necessary for the presentation of the present invention.

1 shows a schematic perspective view of a device 1 for thermal insulation, which is installed between a supported component A and a supporting component B. The component for thermal insulation consists essentially of a thermally insulating body 2 and reinforcing elements in the form of 3 and shear force bars 4 as well as printing elements 5 , The tension rods 3 and the printing elements 5 enforce the thermally insulating body 2 transverse to the substantially longitudinal extent of the thermally insulating body 2 from component A to component B. The transverse force rods 4 enforce the thermally insulating body 2 also transversely to the substantially longitudinal extent of the thermally insulating body 2 from component A to component B, but in mutually parallel vertical planes, the thermally insulating body 2 traverse inclined.

From the view of 1 shows that the reinforcing elements are arranged at regular intervals, wherein the proportion and / or the number of tension rods of the component 1 is designed and elemented for thermal insulation, that the design value of the absorbable tensile force F _{z, Rd of} the tension rods 3 to the extent of the tensile force F _{QZ, Rd} , which can be introduced into the adjacent bearing component, which is the result of the design value of the absorbable tensile force F _{Q, Rd of} at least one transverse force rod 4 and whose inclination angle results, is smaller than the design value of the maximum applied compressive force F _{D, Ed} on the printing elements 5 which is made up of the absorbable loads of the component 1 for thermal insulation results.

Hence the equation: F z, Rd ≤ | FD, Ed | - F QZ, Rd

F_Z,Rd

der Bemessungswert der aufnehmbaren Zugkraft

F_D,Ed

der Bemessungswert der maximal einwirkenden Druckkraft

F_QZ,Rd

die einleitbare Zugkraft zumindest eines Querkraftstabes

Where:

F _{Z, Rd}

the design value of the absorbable tensile force

F _{D, Ed}

the rated value of the maximum compressive force

F _{QZ, Rd}

the introductory tensile force of at least one transverse force rod

Claims (5)

Component system for thermal insulation, consisting of components for thermal insulation, wherein the components for thermal insulation between two components to be concreted, in particular between a supported component (A) and a load-bearing component (B), are installed and to be arranged therebetween a thermally insulating body ( 2 ) with at least integrated printing elements ( 5 ), wherein the pressure elements ( 5 ) in the components ( 1 ) are used for thermal insulation and are part of the components, and integrable train ( 3 ) and transverse force bars ( 4 ), which are transverse to the longitudinal extent of the thermally insulating body ( 2 ) through it and can be connected in each case to both components (A, B), wherein the transverse force rods ( 4 ) in mutually parallel vertical planes the thermally insulating body ( 2 ) inclined, wherein the components are integrated for thermal insulation for different load cases by the proportion and / or the number of reinforcing elements ( 3 . 4 . 5 ) varies in the components for thermal insulation, characterized in that the proportion and / or the number of tension rods ( 3 ) of the respective component for thermal insulation is designed and elemented such that the rated value of the absorbable tensile force of the tension rods ( 3 ) by the amount of tensile force which can be introduced into the adjacent load-bearing component (B), resulting from the design value of the absorbable tensile force of at least one transverse force rod ( 4 ) and its inclination angle, is smaller than the design value of the maximum compressive force acting on the pressure elements ( 5 ), which consists of the absorbable loads of the component ( 1 ) for thermal insulation, wherein the components are arranged for thermal insulation in load groups and wherein within a load group at substantially constant proportion and / or number of tension rods ( 3 ) with the change in the proportion and / or the number of lateral force rods ( 4 ) the proportion and / or the number of printing elements ( 5 ) or within a load group with essentially the same proportion and / or number of printing elements ( 5 ) with the change in the proportion and / or the number of lateral force rods ( 4 ) the proportion and / or the number of tension rods ( 3 ) changes. Component according to Claim 1, characterized in that the rated value of the absorbable tensile force of the tension rods ( 3 ) by the measure the tensile force which can be introduced into the adjacent supporting component (B) and which is determined from the rated value of the absorbable tensile force of at least one transverse force rod ( 4 ) and its inclination angle is smaller than that of the train ( 3 ) and transverse force bars ( 4 ) introducible tensile force in the load-bearing component (B), which consists of the absorbable loads of the component ( 1 ) gives the thermal insulation. Component according to at least one of the preceding claims, characterized in that the proportion and / or the number of tension rods ( 3 ) of the respective component for thermal insulation is designed and elemented such that the rated value of the absorbable tensile force of the tension rods ( 3 ) by the amount of tensile force which can be induced in the adjacent structural member (B), which is the result of the design value of the absorbable tensile force of the transverse force rods ( 4 ) and the angle of inclination of the transverse force bars, is smaller than the rated value of the maximum compressive force acting on the pressure elements ( 5 ), which consists of the absorbable loads of the component ( 1 ) gives the thermal insulation. Component according to at least one of the preceding claims, characterized in that the rated value of the absorbable tensile force of the tension rods ( 3 ) by the amount of tensile force which can be induced in the adjacent structural member (B), which is the result of the design value of the absorbable tensile force of the transverse force rods ( 4 ) and the angle of inclination of the transverse force rods ( 4 ) is less than that of the train ( 3 ) and transverse force bars ( 4 ) introducible tensile force in the load-bearing component (B), which consists of the absorbable loads of the component ( 1 ) gives the thermal insulation. Component according to at least one of the preceding claims, characterized in that the tension ( 3 ) and transverse force rods ( 4 ) are anchored by an overlapping joint with the connection reinforcement in the adjacent component.