EP3348726A1 - Heat insulation device, in particular for heat insulation of buildings or parts of buildings - Google Patents

Abstract

A thermal insulation device, in particular for thermal insulation of buildings or building parts, is described, wherein the thermal insulation device comprises a first heat-insulating part and a second part of the thermal-insulation device. The described thermal insulation device is characterized in that the two heat-insulating device parts are engageable with each other so that they are pivotally relative to each other in the intended mutually engaged state.

Description

The present invention relates to a thermal insulation device according to the preamble of patent claim 1.

Thermal insulation devices for buildings have been known for many years in innumerable embodiments. Among the best known thermal insulation devices include the thermal insulation panels of a thermal insulation composite system. Using such thermal insulation panels, the outer walls of a building can be relatively quickly and easily provided with a very effective thermal insulation. However, almost all buildings have various parts of the building whose thermal insulation requires a disproportionate effort. This includes, for example, the exterior wall area of a building adjoining the eaves with a sloping roof projecting laterally.

This part of the building is in FIG. 7 shown. The FIG. 7 shows a portion of a building exterior wall formed by a wall 101 and a part of the roof of the building. From the roof are in the FIG. 7 a (roof) purlin 102, a (roof) rafter 103, and provided in the eaves area on the underside of the rafters 103 eaves formwork 104 is shown. The purlin 102 is a foot purlin which rests centrally on the wall 101 (or a ring anchor mounted above) and serves as a support for the rafters 103 resting thereon. The outside of the wall 101 is clad using a composite thermal insulation system. Thermal insulation composite system thermal insulation panels 105 and 106 are shown. The lower thermal insulation panel 105 is a "normal" thermal insulation panel, which must have only the correct length and width. The upper thermal insulation panel 106 extends up to the obliquely downwardly extending eaves formwork 104 upwards and must have at its upper end a slope 107, the slope of the Traufschalung 104 corresponds, so that the slope 107 of the thermal insulation board 106 over the entire surface of the eaves formwork 204 comes into contact. Since the slant 107 to be provided may vary from building to building, in most cases it is necessary to tailor the thermal insulation panels 106 individually at the construction site. This is obviously associated with a very large effort. Moreover, even with great care, there is a considerable risk that the thermal insulation panels 106 still do not optimally fit in the gap to be filled.

Similar problems occur in the manufacture of a thermal insulation device, also referred to as purlin insulation. Such a thermal insulation device is also in the FIG. 7 shown and designated there by the reference numeral 108. The thermal insulation device 108 is used to close an existing opening in the building in the building. The said opening is down through the top of the purlin 102, up through the mounted on the top of the rafters 103, in the FIG. 7 Not shown formwork, and bounded to the side by two adjacent rafters 103. The thermal insulation device 108 used to close such an opening may rest on the wall 101, more precisely in which the outer wall section adjacent to the purlin 102 rests and extends up to the aforementioned formwork. This area has hitherto been closed with masonry blocks or with thermal insulation boards. Again, at the upper end of the thermal insulation device 108 adapted to the roof inclination slope 109 must be formed, which rests over the entire surface of the provided on the rafter top formwork. Consequently, the same problems and risks occur as in the production of the thermal insulation panel 106.

The present invention is therefore based on the object to find a way by which thermal insulation devices that must have an individually adapted to the prevailing conditions slope or other labor-intensive Require adjustments, make it quick and easy.

This object is achieved by the claimed in claim 1 thermal insulation device.

The thermal insulation device according to the invention is characterized in that it comprises a first heat-insulating member part and a second heat-insulating member part, which are engageable with each other so that they are pivotally relative to each other in the intended mutually engaged state.

The thermal insulation device according to the invention makes it possible, for example, to align the second part of the thermal insulation device by pivoting it as desired in relation to the part of the building with which it must come into contact. More specifically, it can be achieved only by a corresponding pivoting and in particular without an individual cut of the second heat-insulating part, that a certain surface of the second heat-insulating member is aligned parallel to the surface of the building, with which it must come into contact.

In an advantageous development of the invention, a third heat-insulating part is additionally provided, which can be connected to the first part of the heat-insulating device such that these heat-insulating device parts can be telescoped and pulled apart as intended and without any solution of the connection.

This allows an even more flexible adaptation of the thermal insulation device to achieve the given conditions. In particular, the first heat-insulating part can be positioned with little effort so that the second part of the thermal insulation device can be made even easier and more accurate in its intended location.

The thermal insulation device according to the invention can therefore be much faster and easier individually adapted to the prevailing conditions than is the case with conventional thermal insulation devices.

Advantageous developments of the invention are the dependent claims, the following description, and the figures removed.

Figur 1

eine Seitenansicht eines Gebäudeteils, in welchem die im Folgenden näher beschriebene Wärmedämmvorrichtung als Pfettendämmung verwendet wird,

Figuren 2 und 3

größere Darstellungen der in der Anordnung gemäß Figur 1 als Pfettendämmung zum Einsatz kommenden Wärmedämmvorrichtung,

Figur 4

eine vorteilhafte Weiterbildung der in den Figuren 2 und 3 gezeigten Wärmedämmvorrichtung,

Figur 5

eine Seitenansicht eines Gebäudeteils, in welchem die im Folgenden näher beschriebene Wärmedämmvorrichtung als ein Teil eines Wärmedämmverbundsystems verwendet wird,

Figur 6

eine vergrößerte Darstellung eines Ausschnittes der in der Figur 5 gezeigten Anordnung, und

Figur 7

eine Seitenansicht eines Gebäudeteils, in welchem herkömmliche Wärmedämmvorrichtungen als Pfettendämmung und als ein ähnlich ausgebildeter Teil eines Wärmedämmverbundsystem zum Einsatz kommen.

The invention will be explained in more detail by means of embodiments with reference to the figures. Show it

FIG. 1

a side view of a building part, in which the heat insulation device described in more detail below is used as Pfettendämmung,

FIGS. 2 and 3

larger representations of the arrangement according to FIG. 1 used as purlin insulation thermal insulation device,

FIG. 4

an advantageous development of the in the FIGS. 2 and 3 shown thermal insulation device,

FIG. 5

a side view of a building part, in which the heat insulation device described in more detail below is used as part of a thermal insulation composite system,

FIG. 6

an enlarged view of a section of the in FIG. 5 shown arrangement, and

FIG. 7

a side view of a building part, in which conventional thermal insulation devices are used as Pfettendämmung and as a similarly trained part of a thermal insulation composite system.

The thermal insulation device described in more detail below is a thermal insulation device, in particular for thermal insulation of buildings or parts of buildings.

The described thermal insulation device can be used for various purposes. In the following, in particular the use of the thermal insulation device as Pfettendämmung and as a similarly trained part of a thermal insulation composite system is described in detail. However, it should be noted at this point that the use of the thermal insulation device presented here is not limited thereto. The thermal insulation device can also be used for other purposes on buildings or parts of buildings, and can also be used for thermal insulation of any other objects, so not only for the thermal insulation of buildings and parts of buildings.

In the in the FIG. 1 shown building part, the thermal insulation device presented here is used as Pfettendämmung.

The FIG. 1 shows a part of a building exterior wall formed by a wall 1 and a part of the roof of the building. From the roof are in the FIG. 1 a (roof) purlin 2 and a (roof) rafter 3 shown. The wall 1, the purlin 2 and the rafters 3 correspond to those in the FIG. 7 designated by the reference numerals 101, 102, and 103 components. These components will therefore not be described again here; To avoid repetition will be on the on the FIG. 7 reference description referenced. Furthermore, the shows FIG. 1 the realized by the presented here thermal insulation purlin insulation. The thermal insulation used as purlin insulation is in the FIG. 1 denoted by the reference numeral 8. The thermal insulation device 8 is installed in the same place, closes the same opening in the building, and has the same function as in the FIG. 7 However, the structure of the thermal insulation device 8 differs very significantly from the conventional purlin insulation 108 shown and described with reference thereto.

The structure of the thermal insulation device 8 presented here is particularly in the FIGS. 2 and 3 good to see.

The heat-insulating device 8 includes a plurality of component parts, more specifically, a first heat-insulating member 81 and a second heat-insulating member 82. These heat-insulating members 81, 82 are engageable with each other so as to be properly engaged with each other are pivotable relative to each other.

This is in the FIGS. 2 and 3 illustrated. The FIGS. 2 and 3 show the heat-insulating parts 81, 82 in the intended mutually engaged state. It is such that the first heat-insulating member 81 has a recess 811 on its side facing the second heat-insulating member 82, and the second heat-insulating member 82 on its side facing the first heat-insulating member 81 is complementary to the recess 811 Survey 821 has. The recess and the protrusion may also be interchanged, so that the second heat-insulating member 82 may have a recess on its side facing the first heat-insulating member 81, and the first heat-insulating member may face on the second heat-insulating member Side may have a complementary trained to the recess survey.

The first heat-insulating member 81 and the second heat-insulating member 82 are engaged with each other by inserting the protrusion 821 in the recess 811.

The recess 811 and the elevation 821 are formed such that the heat-insulating device parts 81, 82 are pivotable about a predetermined virtual pivot axis 83, preferably only about this pivot axis 83 relative to each other.

The FIGS. 2 and 3 show two different pivot positions of the heat-insulating parts 81, 82. In the in the FIG. 3 shown thermal insulation device aligned with the heat-insulating device parts 81, 82, so are not pivoted relative to each other. The same relative position, the heat-insulating parts 81, 82 in the FIG. 1 shown purlin insulation 8. This relative position or this swivel angle between the heat-insulating parts 81, 82 was in the in the FIG. 1 chosen arrangement, because in this state, a surface 84 of the second heat-insulating member portion 82 over the entire surface of the roof component abuts, to which it is to extend. The said surface of the second heat-insulating member 82 is a bevel 84 provided at the front end, that is, at the end of the second heat-insulating member 82 remote from the first heat-insulating member 81.

If the roof component to which the second heat-insulating member 82 is to extend should have a different inclination or slope, then only by another pivotal position of the second heat-insulating member 82 with respect to the first heat-insulating member 81 could be achieved in such a case, the slope 84 of the second Heat-insulating part 82 abuts the entire surface of said roof component.

When in the FIG. 2 shown relative position of the heat-insulating parts 81, 82, the second piece of thermal insulation device 82 a piece to the right (relative to in the FIG. 1 shown installation position further to the building) pivoted. As a result, the slope 84 is less steep and could come into full contact with a correspondingly flatter roof.

In a panning, not shown in the figures, the second heat-insulating device part 82 to the left (relative to those in the FIG. 1 installation position shown away from the building), the slope 84 would be steeper and could come into contact with a correspondingly steeper roof over its entire surface.

Thus, by properly pivoting the second heat sink portion 82 relative to the first heat sink portion 81, the second heat sink portion 82 may be placed in such a position that a particular surface thereof is aligned parallel to the building portion to which it is oriented should extend, and in this orientation, the said surface, the second heat-insulating member portion 82 with the relevant part of the building come into contact over its entire surface. This can be achieved solely by a corresponding pivoting of the second heat-insulating device part 82. An additional processing of the wide heat-insulating device part 82, for example, an individual cutting of the same can be omitted.

Trimming the second heat sink portion 82 or other adjustments may still prove advantageous under certain circumstances. The mentioned pivoting of the heat-insulating parts 81, 82 makes namely readjustments possible, so that the cutting or the other operations do not require high precision, so can be done quickly and easily.

In the example considered, the bevel 84 mentioned above is in the area of the second heat-insulating device part 82, which should preferably come into full contact with the building part up to which the second heat-insulating device part 82 should extend. In principle, however, it could also be to act on any other surface of the second heat sink portion 82.

In this area, in the example considered in the slope 84, a recess 85 is provided which extends over the entire length of the slope 84. The recess 85 is designed to receive a Kompribandes, which ensures that any existing leaks between the slope 84 and the building part, with which the slope 84 is to come into contact, are hermetically sealed.

In the example considered, the recess 811 has no undercut, so that in the mutually engaged state of the heat-insulating parts 81, 82, the second heat-insulating parts 82, more precisely its elevation 821 only loosely in the recess 811 and not otherwise on the first Heat-insulating member part 81 is held. However, if necessary, a connection between the heat-insulating parts 81, 82 may be provided.

The recess 811 extends parallel to the virtual pivot axis 83 and extends over the entire side of the heat-insulating part on which it is provided. The same applies to the associated elevation 821. This also runs parallel to the virtual pivot axis 83 and extends over the entire side of the heat-insulating part on which it is provided.

The recess 811 has in the example considered a circular segment-shaped cross-section. The elevation 821 has a corresponding complementary cross-section.

The components of the heat-insulator parts 81, 82 which are to be brought into engagement with each other can, in principle, also be designed in any other way and / or be brought into engagement with each other in any other way.

Regardless of how the components of the two heat sink parts 81, 82 to be engaged are formed and engaged, it is preferable that the heat sink parts 81, 82 are properly engaged with each other regardless of their intended purpose Relative position no air gap between the two heat-insulating parts 81, 82 is present and therefore no air between the two heat-insulating parts 81, 82 can pass.

It may prove advantageous if, as for example FIG. 3 it can be seen, the second heat-insulating member portion 82 is formed less thick than the first heat-insulating member portion 81. Then, in certain installation conditions, larger pivotal movements can be performed (see, for example FIG. 6 ).

The first heat-insulating member 81 is formed in the example considered by a plate. This may essentially be a normal thermal insulation board, as used in the known thermal insulation systems. The only particularity is that it must be engaged with the second heat sink portion 82 as described.

The second heat-insulating member 82 may also be formed by a correspondingly cut plate. Also This may essentially be a normal thermal insulation board, as used in the known thermal insulation systems. The peculiarity is that, as described, it must be able to be brought into engagement with the first heat-insulating part 81 and possibly has the bevel 84 mentioned above. Depending on the design of the bevel 84, the second heat sink portion 82 may take the form of a pivotable wedge.

The first heat-insulating member 81 is adapted to be attached to the building. The second heat sink portion 82 may also be configured to be attached to the building. However, it may also be provided to mount the heat-insulating device parts 81, 82 on the building such that the second heat-insulating part 82 is clamped between the first heat-insulating part 81 and the building and held in its intended position and position by this clamping connection ,

Preferably, the outside of the building to be lying side of the first heat-insulating part 81 is structured with various elevations and / or depressions and provided with a plaster base. This improves the adhesion of a plaster layer applied on this side.

On the underside of the first heat-insulating device part 81 coming to rest below the mounted state, grooves or other elevations or depressions for better adhesion in the mortar bed or in the adhesive foam are preferably provided.

An advantageous development of the thermal insulation device 8 described above is in FIG. 4 shown. The heat-insulating device shown therein includes, in addition to the above-described heat-insulating member parts 81, 82, a third heat-insulating member part 86 adapted to be fitted with the first heat-insulating member part 81 to be connected. More specifically, the first heat-insulating member 81 and the third heat-insulating member 86 are connectable to each other so that the first heat-insulating member 81 and the third heat-insulating member 86 are slidable relative to each other without releasing the joint.

The first heat-insulating member 81 has, at its side facing the third heat-insulating member 86, connecting means for connecting the first heat-insulating member 81 to the third heat-insulating member 86, and the third heat-insulating member 86 is at the first heat-insulating member 81 facing side complementary trained connecting means.

Here, the side of the first heat-insulating member 81 facing the third heat-insulating member 86 is the side of the first heat-insulating member 81 away from the second heat-insulating member 82.

The connection means provided for connecting the first and third heat-insulating part 81, 86 are connecting means designed to produce a tongue-and-groove connection. More specifically, in the example under consideration, a recess (groove) is provided in the first heat-insulating member 81, and a complementarily-formed projection (spring) is provided in the third heat-insulating member 86. The arrangement of tongue and groove can of course be reversed.

The first and third heat-insulating member 81, 86, in particular, their connecting means provided for interconnection are formed so that the first heat-insulating member 81 and the third heat-insulating member 86 can be infinitely pushed together and pulled apart as desired.

In the FIG. 4 a state is shown in which the first heat-insulating member 81 and the third heat-insulating member 86 are relatively far apart. The two parts could be pulled even further apart. But they could also be pushed further together. Such a stepless displaceability allows the height of the thermal insulation device to be varied in a very simple manner or to be adapted to the given conditions as desired.

If necessary, instead of in the FIGS. 2 and 3 shown thermal insulation device in the FIG. 4 shown thermal insulation device can be used. This requires no special precautions and is easily feasible. That means, also in the FIG. 4 shown, even more flexible thermal insulation device can be used as Pfettendämmung.

The third heat-insulating member 86 is formed in the example considered by a plate. This may essentially be a normal thermal insulation board, as used in the known thermal insulation systems. The only special feature is that it has to be connected to the first heat-insulating part 81 as described.

Preferably, the outside of the building to be lying side of the third heat-insulating device part 86 is structured with various elevations and / or depressions and provided with a plaster base. This improves the adhesion of a plaster layer applied on this side.

Grooves or other elevations or depressions for better adhesion in the mortar bed or in the adhesive foam are preferably provided on the lower side of the third heat-insulating device part 81 coming to rest in the assembled state below.

It will be understood and need not be further explained that the combination of the first heat-insulating member 81 and the third heat-insulating member 86 alone, that is, without providing the second heat-insulating member 82, is also advantageous. In this way, a normal thermal insulation board with infinitely variable height and / or infinitely variable width could be created. As a result, individual blanks of the thermal insulation panels for adaptation to the given conditions can be avoided, at least in certain cases.

Of course, in the absence of a second heat-insulating member 82, the top of the first heat-insulating member 81 need not have a recess 811 for the second heat-insulating member 82, but may be formed at this location as a "normal" heat-insulating panel.

Another possible use for the described thermal insulation device according to the FIGS. 2 and 3 is in FIG. 5 illustrated. The FIG. 5 shows a part of a building, more precisely a part of a building wall wall formed by a wall 1 and a part of the roof of the building. From the roof are in the FIG. 1 a (roof) purlin 2, a (roof) rafter 3, and a eaves formwork 4 shown. The outside of the wall 1 is clad using a composite thermal insulation system. From the thermal insulation composite thermal insulation panels 5 and 8 are shown.

The wall 1, the purlin 2, the rafters 3, the Traufschalung 4 and the thermal insulation board 5 correspond to those in the FIG. 7 with the reference numerals 101, 102, 103, 104 and 105 designated components. These components will therefore not be described again here; To avoid repetition will be on the on the FIG. 7 reference description referenced.

The thermal insulation board 8 is in the FIGS. 2 and 3 shown thermal insulation device and replaced the conventional thermal insulation board 108 according to FIG. 7 ,

That is, the heat-insulating device 8 is not only as Pfettendämmung (see FIG. 1 ), but also as part of a thermal insulation composite system used. The achievable advantages are the same. When in the FIG. 5 shown use for the thermal insulation device 8, the pivoting range of the second heat-insulating device part 82 is limited. In particular, the second heat-insulating member 82 can not be pivoted so far back because there is the wall 1 of the building. As in particular from FIG. 6 it can be seen that the second heat-insulating device part 82 at least a little backwards (to the wall 1) can be pivoted, and forward yes anyway.

Even with such a use of the heat-insulating element 8, if necessary, in the alternative FIG. 4 shown thermal insulation device are used.

For the sake of completeness, it should finally be mentioned that all the heat-insulating device parts 81, 82, 86 are made of good heat-insulating material, preferably of foamed plastic such as foamed polystyrene or of the product sold under the name Neopor. Of course, all other materials come into question, which are used for the production of thermal insulation boards or the like or can be used.

It may prove advantageous if the heat-insulating parts 81, 82, 86 are made of materials of different hardness or different compressibility. In particular, it could be provided that lighter and / or more compressible materials are used in the hard to reach areas of the building. That is, it could for example be provided make the second heat-insulating member 82 of softer material than the other heat-insulating members 81, 86.

The heat-insulating device described above proves to be advantageous in many respects regardless of the details of the practical implementation. As a result, fewer blanks on the construction site and no longer any oblique blanks are required, and less waste is produced.

LIST OF REFERENCE NUMBERS

1

Wall

2

(Roof) purlin

3

(Roof) rafters

4

Traufschalung

5

Insulation Board

8th

used as purlin insulation thermal insulation device

81

first heat-insulator part

82

second heat-insulator part

83

virtual pivot axis

84

Slanting at 82

85

Exit in 84

86

third heat-insulator part

811

Deepening in 81

821

Survey at 82

101

Wall

102

(Roof) purlin

103

(Roof) rafters

104

Traufschalung

105

thermal insulation board

106

thermal insulation board

107

Sloping at 106

108

Pfettendämmung

109

Sloping at 108

Claims (15)

Heat insulation device, in particular for thermal insulation of buildings or building parts, wherein the thermal insulation device comprises a first heat-insulating device part (81) and a second heat-insulating device part (82), characterized in that the two heat-insulating device parts are engageable with each other in that conditionally engaged with each other state are pivotally relative to each other. Thermal insulation device according to claim 1, characterized in that the two heat-insulating device parts (81, 82) are formed so that in the intended mutually engaged state thereof regardless of their relative position no air gap between the two heat-insulating device parts is present. Heat-insulating device according to one of the preceding claims, characterized in that of the heat-insulating device parts (81, 82) at least the first heat-insulating device part (81) is formed by a thermal insulation board. Heat-insulating device according to one of the preceding claims, characterized in that at least one of the heat-insulating device parts (81, 82) is adapted to be attached to the building. Heat-insulating device according to one of the preceding claims, characterized in that , relative to the state in which the heat-insulating device parts (81, 82) are intended to engage with each other, - One of the heat-insulating parts (81, 82) on its side facing the other heat-insulating member part has a recess (811), and - The other part of the thermal insulation device on its side facing the heat-insulating member part has a complementary to the recess formed elevation (821). Thermal insulation device according to claim 5, characterized in that the recess (811) and the elevation (821) extend parallel to a virtual pivot axis (83) about which the heat-insulating device parts (81, 82) are pivotable relative to each other. Heat-insulating device according to claim 5 or 6, characterized in that the recess (811) has a circular segment-shaped cross-section. Heat-insulating device according to one of the preceding claims, characterized in that the second heat-insulating device part (82) is formed by a wedge. Heat-insulating device according to one of the preceding claims, characterized in that the second heat-insulating device part (82) is adapted to be clamped in the intended mounted on the building state of the thermal insulation device between the first heat-insulating member (81) and the building and through this clamp connection to be held in his position and position. Heat-insulating device according to one of the preceding claims, characterized in that the second heat-insulating device part (82) is designed to come into contact with a surface (84) formed on the entire surface with a bevel present on the building. Thermal insulation device according to claim 10, characterized in that in the surface of the building (100) to be brought into contact surface (84) of the second heat-insulating device part (82) is formed a recess (85) for inserting a Kompribandes. Heat-insulating device according to claim 10 or 11, characterized in that the surface (84) of the second heat-insulating device part (82) to be brought into contact with the building bevel is formed by a bevel at the end of the second heat-insulating device part (82). is provided, which faces away from the first heat-insulating device part (81) in the intended mutually engaged state of the heat-insulating device parts. Thermal insulation device according to one of the preceding claims, characterized in that the second heat-insulating device part (82) has a smaller thickness than the first heat-insulating device part. The heat-insulating device according to any one of the preceding claims, characterized in that the heat-insulating device further comprises a third heat-insulating member (86) connectable to the first heat-insulating member (81), and in the intended condition of the first and third heat-insulating member parts connected Wärmedämmvorrichtungs parts without a solution of the compound as desired are far together collapsible and auseinanderziehbar. A thermal insulation device according to claim 14, characterized in that the side of the first heat-insulating member (81) facing the third heat-insulating member (86) is the side of the first heat-insulating member facing away from the second heat-insulating member (82).

Images