EP0866185A2 - Thermal insulation system - Google Patents

Abstract

The system for heat insulation with an insulated construction element built in between a building wall and a part branching off from it consists of an insulating body with integrated fastening elements extending across the body and through it, connected on both sides to the building wall and the branching-off part. At least one part of the fastening elements is on the side of the body pointing to the building outside with their projecting lengths to be embedded in an edge beam. To insulate a part branching off on the building inside, the insulating body is located at least predominantly outside the building wall cross-section on its inside and the edge beam runs inside the wall cross-section.

Description

The invention relates to a system for thermal insulation with an insulating, between a building wall and a branching one Component to be installed, consisting of an intermediate one insulating body to be installed with integrated reinforcement elements, which extend transversely to the insulating body through this and on both sides with the building wall or the branching component in Are operatively connected, at least some of the reinforcement elements on the side of the insulator facing the outside of the building is to be concreted in with a protrusion in an edge beam.

Such thermal insulation systems are known as so-called Clinker pad used, with the edge beam on the outside the wall of the building protrudes and the one on the outside of the building cladding facing masonry. For thermal insulation in this case the edge bar is through the insulating body of the horizontally branching component, i.e. the adjoining one Ceiling plate and the building wall, separated, but over the reinforcement elements connected to despite the thermal insulation serving distance between edge beams and ceiling slab sufficient load-bearing capacity for the facing masonry is available to deliver.

Proceeding from this, the present invention is based on the object the system for thermal insulation of the above Modify type so that it can be used for other applications is.

This object is achieved in that for insulation a component of the insulating body branching off inside the building at least predominantly outside the building wall cross-section is arranged on the inside and that the edge bar runs within the building wall cross-section.

In certain regional areas there is thermal insulation enforced on the inside of the building wall, but so far had the disadvantage that on the inside of the building walls Insulating bodies could be provided for thermal insulation, but the ceiling slab resting on the building wall or the the building walls adjoining the inner walls are not opposite the Building exterior could be decoupled. This was on the inside of the building in the transition area between the ceiling tile and building wall or between the inner and outer wall of the uninsulated connection parts moisture or condensation problems preprogrammed.

The present invention now transfers the edge bar element for superimposing facing masonry on the present one Insulation problem. For this purpose, the Edge beams not only to support the relatively low weight of the facing masonry and as a supported external component used, on the contrary the edge beam is used as an anchoring component moved into the building wall and on this Edge beams suspended the entire ceiling slab or the inner wall connected. Here, the effective component forces from the edge beam coupled via the reinforcement elements added, with at least some of the reinforcement elements, namely in particular the tensile and shear bars in the Edge beams with theirs on the outside of the building supernatants are concreted. In the edge bars the anchoring length of the reinforcement elements expediently lengthened by being either perpendicular to their horizontal The course is bent - in the case of tension and shear bars below - and thus run parallel to the outer wall of the building, or that they have vertical anchor plates at their ends, which in particular applies to the pressure rods. On the side of the ceiling plate or Inner wall there is no problem of limited space, which is why the reinforcement bars are usually straight horizontal Show course.

As already indicated, the present invention relates to the thermal insulation of two types of branching components, namely on the one hand on a horizontal floor or ceiling plate and on the other hand a vertically branching inner wall. At the bottom or The ceiling slab is the edge beam and that from the reinforcement elements and the insulating body existing component for thermal insulation also arranged in a horizontal direction, while in the vertical inner wall the elements mentioned above and the connected edge beam run in the vertical direction.

The two types of components differ not only in their orientation from each other, but also in the reinforcement elements: The floor or ceiling plate becomes a large part of that associated edge beams worn, which is why advantageously as Reinforcement elements tension, compression and shear bars installed to both the continuously acting weight forces also take on any external impacts can; in contrast, the inner walls do not need to be necessarily from the vertical edge bar or the one surrounding it Building wall in the direction of tension and compression are relieved, essential in this context is the inclusion of Lateral forces that occur in both the horizontal and vertical directions can.

As far as the shear bars of both component plates are concerned, they can expediently be bent vertically and starting from Enter the edge bar into the insulating body at the top, sloping it downwards traverse and go below into the branching component. Likewise, it can also be advisable to turn horizontally Provide shear bars starting from the branching component run horizontally, enter the insulator vertically, it Cross at an angle in the horizontal plane and cross into the Pass the edge bars at an angle in the opposite direction.

To the lateral forces in both the horizontal and vertical directions to be able to absorb in the opposite direction of action, these shear bars can also be a mirror image of the former be arranged and thus for example from the branch Starting from the top, enter the component into the insulating body, at an angle cross down and merge into the edge beam below; For the horizontal shear bars apply accordingly. Particularly advantageous it is, however, if these transverse force rods are mirror images provided together with the first-mentioned shear bars in order to absorb forces in both directions. Here, two of the mirror images can be used Shear bars are integrally connected, the Connection is made via a loop-shaped course in the edge beam, and both interconnected shear bars in the insulating body cross. Accordingly, the mirror plane is for the gradient the second group of shear bars arranged vertically in the insulating body. The resulting stiffening cross transfers horizontal bwz. vertical relative movements between edge bars and component in both positive and negative directions and catches this due to the corresponding inclination in the insulating body Tension loaded shear bars. The same applies, of course, if each of the bars running in mirror image without connection in parallel Layers are arranged.

As for the insulating body installed on the inside of the building, this advantageously runs approximately flush with the remaining inner insulation the building wall, so that cold bridges are excluded are. The inside of the insulating body thus protrudes expediently at most as far into the interior of the building as one along the Building wall-mounted interior insulation, the insulating body in addition, it is best to totally outside the cross-section of the building wall is arranged around the load-bearing underside of the ceiling edge beam not affect their size. Regarding the inside the building wall it is also recommended that the to the inside of the end face of the edge beam is offset no continuous joint with the inside of the building wall form. This is not just constructive, but in particular also advantageous from a sound engineering point of view.

On the other hand, it is also recommended that the edge bar is narrower than the building wall, and that on the outside remaining space is filled with a storage part that expediently from a masonry stone of the same material how the outer wall of the building exists, in order to apply it to it Plaster evenly and corresponding to the building wall Surface to offer. Both vertically and horizontally oriented edge bars it is possible, on the one hand, that this Edge beams as separate from the building wall surrounding it Component is formed, which can be done, for example, that a building wall made of bricks has a corresponding one Recess for the edge beam consisting of in-situ concrete has: on the other hand, the edge beam can also be made in one piece with the building wall be connected and for example together with this be made of in-situ concrete, the edge bar only on the recognizable reinforcement for the branching component is.

As far as the reinforcement elements are concerned, the Tensile and compressive forces expediently by separate tensile and Pressure elements that can be rod-shaped. As opposed to it simplified alternative it is also possible to combine Tension / compression reinforcement elements to be provided as being approximately medium Height of the insulator approximately horizontal bars are trained. As a result, they are between the printing and the Traction zone arranged and can both types of force by one element record, taking care when positioning them must be that in the upper or lower edge area of the insulating body no gap too large compared to the edge beam or the branching Component due to any mutual inclination arises.

It is recommended to improve the absorption of the respective forces also end up on the various reinforcement elements To provide bearing plates, primarily by the anchoring length can be reduced in the on the thickness of the building's outer wall reduced edge bar is reduced anyway.

In this context, it is when using separate tension rods in addition, it is recommended to place these in the edge bar of the tension zone starting in the area facing away from the insulating body for example, to bend down to make up for the shortcoming the reduced depth of the edge bar.

While in buildings with conventional external insulation, two floors or rooms through the one extending into the outer wall of the building Ceiling plate or inner wall are separated from each other now the insulating body connects between the two neighboring ones Spaces, which is why it is particularly important that the insulating body on its outer sides, ie above and / or below in In the case of the ceiling connection or left and / or right in the case of the Inner wall connection with protective plates against the environment is covered, which expediently with the outsides of the branch Align component. As a rule, it is recommended if the protective plates are flush with the outside of the insulator ends with respect to the top of the ceiling panel connector arranged protective plate, it is particularly advantageous if the plate on both sides of the insulating body in the adjacent components protrudes because this area is under tension and thereby prevents the formation of a gap between the insulating body and the concrete components can be.

These panels not only allow fire protection, but in particular also a sound insulation decoupling two floors or rooms. These protective plates can for this the ceiling plate or inner wall connection opposite the Seal the environment and to achieve fire protection from fire retardant or solid material. It is very general Recommended for the protective plates if they are made of plastic foam (for example polystyrene) or with appropriate fire protection Requirements from a mineral porous fiber insulation (e.g. mineral wool).

In addition to the protective plates, it is expedient to between a joint tape is also arranged between the two concrete components crosses the insulating body and in both adjacent components is anchored and made of air- and / or waterproof and tear-resistant Material can exist in terms of sound, moisture and Odor transmission the decoupling of the two floors or Ensure spaces.

Figur 1

ein erfindungsgemäßes vereinfachtes Wärmedämmsystem für Deckenplatten in geschnittener Seitenansicht;

Figur 2

eine alternative Bauform eines erfindungsgemäßen Wärmedämmsystems für Deckenplatten ebenfalls in geschnittener Seitenansicht;

Figur 3

eine Alternative zur Bauform aus Figur 2 in etwas aufwendigerer Bewehrungselementbestückung in geschnittener Seitenansicht;

Figur 4

die Bauform aus Figur 3 in Draufsicht;

Figur 5

ein erfindungsgemäßes Wärmedämmsystem für den Anschluß von Innenwänden in geschnittener Draufsicht; und

Figur 6

das Wärmedämmsystem aus Figur 5 in geschnittener Seitenansicht.

Further features and advantages of the present invention result from the following description of exemplary embodiments with reference to the drawings; show here

Figure 1

an inventive simplified thermal insulation system for ceiling tiles in a sectional side view;

Figure 2

an alternative design of a thermal insulation system according to the invention for ceiling tiles also in a sectional side view;

Figure 3

an alternative to the design of Figure 2 in a slightly more complex reinforcement element assembly in a sectional side view;

Figure 4

the design of Figure 3 in plan view;

Figure 5

an inventive thermal insulation system for the connection of inner walls in a sectional plan view; and

Figure 6

the thermal insulation system of Figure 5 in a sectional side view.

In Figure 1, a system for thermal insulation is shown between a vertical building wall 1 and one branching from it horizontal ceiling plate 2 is arranged. The thermal insulation system has an insulating component 3, which consists of an insulating body 4 with integrated reinforcing bars 5, 6, which is extend across this. The insulating body, for example, from Fiber insulation or plastic foam is aligned with one Thermal insulation 7, which is arranged on the inside of the building wall 1 is.

The reinforcing elements 5, 6 crossing the insulating body are made from a combined tension / compression rod 5, which is approximately in the Middle of the height of the component 3 is arranged and for receiving of compressive and tensile forces, whereby it serves for better anchoring has terminal anchor plates 8. As another reinforcement element a transverse force rod 6 is provided, which is in the insulating body 4th on its side facing the building exterior, there Coming from above, runs diagonally down to the insulator to leave on the inside of the building in the lower area and pass horizontally into the adjacent ceiling tile 2.

The insulating body 4 is made in several parts in order to insert the Reinforcement elements 5, 6 to facilitate. Here, the Partition plane between two parts of the Insulating body such that they with those running in the insulating body Reinforcing element sections coincide.

On the side of the insulating body facing the building 4, a ceiling edge beam 9 is provided, which with the building wall 1 is aligned and to transmit the support forces of the ceiling tile 2 serves on the building wall 1. The transverse force rod 6 extends loop-shaped in the ceiling edge beams 9, after a horizontal course in the upper traction area near the outside is angled downwards in a vertical area and then there Crossing the almost complete height of the ceiling edge beam in the Printing area runs again on the ceiling plate 2. This loop-shaped The course serves to increase the anchoring length of the Shear bars in the ceiling edge beam. Because the relatively narrow Ceiling edge beam 9, which corresponds to the depth of the building wall 1, must the total forces and moments exerted by the ceiling plate 2 record and transmit despite its limited dimensions can.

As can be seen in FIG. 1, the thermal insulation system according to the invention the building wall together with the ceiling edge beam completely decoupled from the ceiling plate 2, so that the prevailing disadvantages of internal thermal insulation, for example, an unavoidable additional heat flow via the connection areas or condensation of water vapor in the corner areas.

The sequence when assembling the thermal insulation system according to the invention can look like this, for example: The building wall 1 is bricked up to the floor, then it is used as a prefabricated component trained ceiling tile positioned using a support structure, where the reinforcement elements are already provided by the manufacturer on the ceiling slab 5, 6 and the insulating body 4 molded or molded are. This is followed by a 9 in the area of the later ceiling edge beam Connection reinforcement 10 used, consisting of several horizontally in the Level of the building wall extending bars, which at least partly rest on the reinforcement of the ceiling slab. After the installation of formwork on the outside of the building wall the ceiling edge beam 9 made of in-situ concrete, the insulating body 4 and the building wall 1 the other parts of the concrete formwork form. After the concrete has hardened, the building wall then further bricked up and finally removed the support structure and finally the inner insulation 7 added.

The thermal insulation system shown in Figure 2 corresponds in principle forth from that of Figure 1. Also here is between a ceiling tile 12 and a building wall 11 an insulating component 13 is arranged, that of an insulating body 14, from itself through the insulating body transverse shear rods 16 extending therefrom as well as in this Case not combined, but separate horizontally running Tension rods 15a and compression rods 15b. The tension rods 15a run in the upper region of the ceiling panel 12 parallel to the latter Top and from there through the insulating body into one Ceiling edge beam 19 on the outside of the building Side of the insulating body is arranged in the building wall 11. After a horizontal course, go in the ceiling edge beam 19 the tie rods 15a into a vertical course to similar to that Loop of the shear bars 16, the shear bars 6 of Figure 1 correspond to achieve the required anchorage length.

As can be seen from Figure 2, the ceiling edge beam 19 is narrower formed as the building wall 11, the one on the outside remaining free space with a storage part 20 in the form of a masonry stone is filled in to be applied to the building wall 11 Plaster to offer a similar surface that the position of the ceiling tiles.

The push rods 15b extend parallel to the tension rods 15a lower ceiling tile area and stand up to the ceiling edge beams 19 before where they end with a terminal anchor plate 21.

Unlike the insulating body 4 from FIG. 1, the insulating body 14 from Figure 2 on its top and bottom protective plates 22a and 22b, which cover or seal it from the environment and, for example, fire-retardant or sound-absorbing Material. While the protective plate 22a is offset to the insulator sides runs and protrudes into the adjacent concrete components, closes the protective plate 22b flush with the outside of the Insulating body. Furthermore, the insulating body 14 is in the entry area of the transverse force bars 16 with those indicated by dashed lines in FIG. 2 Recesses 14a, 14b provided by a concrete cover and better introduction of force into the concrete of the bent rod areas already running in the insulating body is achieved.

Figure 3 shows a roughly the same as the thermal insulation system of Figure 2 Embodiment in sectional side view and figure 4 shows this design from FIG. 3 in a sectional plan view.

There branches from a building wall 31 in the horizontal direction Cover plate 32 from, the connection between the cover plate and Building wall takes place via a component for thermal insulation 33. The component consists of a between the ceiling tile and the building wall arranged insulating body 34, from tension rods 35a Compression bars 35b and from vertically angled shear bars 36. These reinforcing bars extend from the ceiling component through the insulating body in a ceiling edge beam 39 in one the type corresponding to the design from FIG. 2.

As an additional reinforcement element are horizontally angled Shear bars 37a and 37b are provided, each approximately in the middle Height run and their bends in particular the horizontal section can be seen from Figure 4. This horizontally angled Shear bars 37a and 37b run in different Horizontal planes. In this case, the ceiling plate in FIG. 4 is wider Shear force rod 37a shown above also in FIG. 3 above of the other rod 37b, both rods being both cross in the insulating body and in the area of the edge beam 39 or overlap. Run to increase the anchor length the bars in the edge beam over a certain distance parallel to the insulating body in opposite directions until they are adjacent Cross reinforcement elements 35a and 36.

Since the transverse force rods 37a and 37b obliquely insulate the body 34 traverse, they will be parallel to the longitudinal extent in this area forces acting on the insulating body are each subjected to tension, whereby they are also between the ceiling component 32 and the building wall 31 or the horizontal bar 39 occurring horizontal Intercept forces without causing them to bend would.

While the pressure bars 35b and the vertically angled shear bars 36 in the embodiment according to FIG. 3 2 correspond, the tension rods 35a are within their course of the edge bar 39 is slightly different from the design from FIG 2 trained. So they are after their horizontal entry into the Edge bar 39 angled approximately U-shaped in the vertical plane, so that they are horizontal again in the lower edge bar area Insulating body taper.

The underside of the ceiling slab 32 consists of a prefabricated concrete slab 32a, which is also used as lost formwork for in-situ concrete the ceiling plate 32 acts. Otherwise, the designs correspond from Figures 2 and 3 each other, for example by the insulating body 34 via horizontal Protective plates 22a and 22b are covered with respect to the environment and the ceiling edge beam 39 via a storage part 20 to the outside of the building is disguised.

Only one additional feature is still in the area of FIG Insulating body 34 provided: there is something below the protective plate 22a a joint tape 38 is arranged, which extends in the horizontal direction along the joint between ceiling edge beam 39 and ceiling tile 32 extends and is molded into these two components, so the The top of the joint is airtight and / or watertight from the bottom of the joint decouple. This joint tape 38 can for example consist of a tear-resistant film material consist of both some relative movements between the two components as well as that when setting of the concrete occurring setting movements absorb in an elastic manner can.

Figure 5 shows a further application of an inventive Thermal insulation system in a sectional plan view and FIG. 6 the component used for thermal insulation in cut Side view. This further application relates to the connection an inner wall 41 to a building outer wall 42, which with an inner insulation 43 is provided. Now that the inner wall 41 has this insulation layer 43 must cross to 42 in the building outer wall The thermal insulation system according to the invention has the ability to be anchored a component for thermal insulation 44 on the mechanical connection between the inner and outer wall and secondly ensures their thermal decoupling. There is the component for thermal insulation 44 from a separate Isolierkorper 45, which runs along the end face of the inner wall 41, from an edge beam 46, which is in a recess in the building wall 42 extends over the entire height of the inner wall, and from Reinforcement elements 47, the edge bar 46 with the inner wall 41 by crossing the insulator 45.

In the simplest case, the reinforcement elements 47 consist of a U-shape angled shear bars that are in a horizontal plane starting from the inner wall through the insulating body in the Extend edge bars, there are angled U-shaped and parallel to run their first U-leg back into the inner wall 41. These shear bars that are even over the height of the inner wall are used to absorb lateral and horizontal forces, which, for example, by setting movements when setting of the mortar or concrete or through to the outer or inner wall transmitted forces are caused.

Since the inner wall 41 is generally self-supporting, it does not have to be separate via tension and compression bars in the edge beam 46 of the building's outer wall be anchored, however, this may apply to certain Definitely recommend constructions. Likewise, vertically angled shear bars are provided for relative movements or to absorb moments and forces in the vertical direction.

The edge bar 46 can - as shown in Figure 5 - in one slot-shaped recess of the outer wall 42 of the building Run inside in the area of the inner wall connection, the The outer wall is usually made of masonry bricks and the edge beams 46 be made from in-situ concrete. On the other hand, it is also possible the edge beam 46 together with the outer wall 42 made of in-situ concrete to manufacture, with both elements connected in one piece are.

From Figure 5 it can also be seen that the inner insulation 43 the building wall 42 and the insulating body 45 of the inner wall connection offset to each other, what to avoid a continuous joint between the two adjacent to the inner wall Is recommended.

In summary, the advantage of the present invention is that that even in buildings with internal insulation, building walls of horizontal components branching off from it, such as Ceiling panels or inner walls can be decoupled, so that Indoor climate in such buildings with that of buildings External insulation corresponds to which such insulation problems in Transition area between building walls and ceiling panels or Interior walls are strange in themselves. On the one hand, this becomes a kind of ring anchor used in the form of the ceiling edge beam, the ceiling tile on the building wall in a greatly reduced section Area, which is why the reinforcement elements such as shear and Tension rods an angled or loop-shaped course exhibit. On the other hand there are vertical edge beams in the building wall provided, on each of which the end face of the to be connected Anchored inside wall.

Claims (20)

System for thermal insulation with an insulating component to be installed between a building wall and a component that branches off therefrom, consisting of an insulating body to be laid between them with integrated reinforcement elements that extend transversely to the insulating body and operatively connected on both sides to the building wall or the branching component stand, with at least some of the reinforcement elements on the side of the insulating body facing the building exterior having to be concreted into an edge beam,
characterized,
that for the insulation of a component (2, 12, 32, 41) branching off inside the building, the insulating body (4, 14, 34, 45) is arranged at least predominantly outside the cross-section of the building wall (1, 11, 31, 42) on the inside thereof and that the edge beam (9, 19, 39, 46) runs within the building wall cross-section. Thermal insulation system according to claim 1,
characterized,
that the branching component (2, 12, 32) is a horizontal floor or ceiling plate, and that this plate over the reinforcement elements (5, 6, 15a, 15b, 16, 35a, 35b, 36, 37a, 37b) and in Border beams (9, 19, 39) extending horizontally are supported on the building wall (1, 11, 31). Thermal insulation system according to claim 1,
characterized,
that the branching component (41) is a vertical inner wall which is anchored in the building wall (42) via the reinforcement elements (47) and the vertical bar (46). Thermal insulation system according to at least one of the preceding claims,
characterized,
that the reinforcement elements include vertically bent transverse force rods (6, 16, 36), which, starting from the edge beam (9, 19, 39), enter the insulating body (4, 14, 34) at the top, cross it obliquely downwards and into the branching components at the bottom (2, 12, 32). Thermal insulation system according to at least one of the preceding claims,
characterized,
that the reinforcement elements include horizontally bent transverse force bars (37a, 37b), which, starting from the branching component (32), enter the insulating body (34) vertically and run horizontally, cross it at an angle in the horizontal plane and angled in the opposite direction in the edge beam (39) pass over. System for thermal insulation according to one of claims 4 or 5,
characterized,
that, in addition to the vertically and / or horizontally bent transverse force rods (37a), transverse force rods (37b) extending in mirror image are provided. System for thermal insulation according to claim 6,
characterized,
that one of the shear bars is integrally connected to a shear bar that runs in mirror image, that the connection is made in a loop shape in the edge beam, and that the two shear bars cross in the insulating body. Thermal insulation system according to at least one of the preceding claims,
characterized,
that the inside of the insulating body (4) projects at most as far into the interior of the building as an internal insulation (7) attached along the building wall (1). Thermal insulation system according to at least one of the preceding claims,
characterized,
that the insulating body (4, 14, 34) is arranged totally outside the building wall cross-section (1, 11, 31). Thermal insulation system according to at least one of the preceding claims,
characterized,
that the edge bar (19, 39) is narrower than the building wall (11, 31) and that the free space remaining on the outside is filled with a storage part (20), in particular a masonry stone of the same material as the building wall. Thermal insulation system according to at least one of the preceding claims,
characterized,
that the absorption of tensile and compressive forces takes place by combined tensile / compressive reinforcement elements (5). System for thermal insulation according to claim 11,
characterized,
that the combined tension / compression reinforcement elements (5) are designed as approximately horizontally extending bars in approximately the middle height of the insulating body (4). Thermal insulation system according to at least one of the preceding claims,
characterized,
that the reinforcement elements (5, 15b, 35b) carry end anchor plates (8, 21). Thermal insulation system according to at least one of the preceding claims,
characterized,
that the insulating body (14, 34) is covered with protective plates (22a, 22b) from the surroundings. Thermal insulation system according to claim 14,
characterized,
that the protective plates (22a, 22b) run flush with the outside of the branching component (12, 32). Thermal insulation system according to claim 14,
characterized,
that the protective plate (22a) arranged on the upper side of the insulating body (14) protrudes in relation to the outer sides of the insulating body in the edge beam (19) and / or the branching component (12). Thermal insulation system according to at least one of the preceding claims,
characterized,
that an air- and / or moisture-tight joint tape (38) is arranged in the area of the insulating body (34), which extends between the edge bar (39) and the branching component (32) and is anchored therein. Thermal insulation system according to at least one of the preceding claims,
characterized,
that the end face of the edge beam (46) lying on the inside of the building and the inside of the building wall (42) run offset from one another. Thermal insulation system according to at least one of the preceding claims,
characterized,
that the edge beam is integrally connected to the building wall. Thermal insulation system according to at least one of the preceding claims,
that the edge beam (9, 19, 39, 46) is designed as a separate component from the building wall (1, 11, 31, 42).

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