DE102007046986A1 - Heat-insulation lining manufacturing method for building facade, involves covering free broad surface of heat insulating unit by forming lower density blowing glass layer and higher density blowing glass layer one above other - Google Patents

Abstract

The method involves covering a free broad surface of a heat insulating unit (2) by forming a lower density blowing glass layer (5) and a higher density blowing glass layer (6) one above the other, where the heat insulating unit comprises an attachment broad surface (3) turned towards a building surface and the free broad surface turned away from the attachment broad surface. The heat insulating unit is attached to the building surface, where the heat insulating unit is made of melamine resin foam material, cotton staple fleece, glass fiber fleece or mineral wool. An independent claim is also included for a wall element comprising a heat insulating unit.

Description

The Invention relates first a method for producing a thermal insulation panel for arrangement to a building, for example, to a building facade, with a thermal insulation element that one of the building surface facing Mounting broad surface and one of the mounting broad surface facing away from wide free surface.

such Procedures are known in construction. For thermal insulation, for example, a building facade this facade will be outside with thermal insulation elements, for example, covered in the form of foam boards. To a sufficient To provide weather protection such thermal insulation elements continue, for example provided with a plaster layer.

in the With regard to the known prior art is a technical Problem of the invention seen therein, a method of in question standing style to improve so that a thermal insulation panel with extended Application spectrum can be achieved

These Problematic is first and essentially solved by that the free wide area of the thermal insulation element covered by a swelling layer becomes. expanded glass or even foam glass has heat-insulating and about that In addition, waterproof properties. As a result, such are Thermal insulation panels Also suitable for the arrangement of moisture applied wall areas, so For example, in the area of tunnel entrances, swimming pools, wet areas, etc. In addition, the applied Blähglasschicht pressure resistant, which also provides protection of the covered thermal insulation element offers pressure. About that In addition, the layer of expanded glass proves to be vapor-tight, not combustible and acid-resistant, moreover pest-proof. Another advantage of the expanded glass layer lies in the existing dimensional accuracy. A cover created in this way also has increased thermal insulation properties on.

Further Features of the invention are below, also in the figure description, often in their preferred association with the subject-matter of the claim 1 or explained features of further claims. But you can also in an assignment to only individual features of the claim 1 or the respective further claim or in each case independently of Meaning.

So is provided in a development of the subject invention, that the free wide area of the thermal insulation element of two superimposed Blähglasschichten covered becomes. These are applied one after the other and can go beyond that at least approximately have the same layer thicknesses. Alternatively, the layer thicknesses of two layers of expanded glass also be different. In a preferred embodiment, the free wide area the thermal insulation element of two on top of each other arranged, different densities having Blähglasschichten covered. So is a blown glass layer with thicker expanded glass particles provided as the other Blähglasschicht. About that can out also more than two superimposed Blähglasschichten, which further optionally have different densities applied become.

In preferred embodiment, the Blähglasschicht is lower density, d. H. the layer with opposite the Blähglasschicht higher Dense larger expanded glass particles, directly on the thermal insulation element applied. The outer layer the thermal insulation panel is formed accordingly by the expanded glass layer of higher density.

The so designed thermal insulation panel can be factory prefabricated in another embodiment. The expanded glass layers are accordingly factory already on the thermal insulation element applied. The so designed thermal insulation panel may in this case be accommodated, for example, in a frame part, which of fixing the thermal insulation panel for example, on the building facade serves. Alternatively you can also in the course of producing the thermal insulation panel in the Blähglasschichten anchored mounting bolts or other types of fixing elements arranged be.

alternative becomes the thermal insulation element first on the building surface, for example at the building facade in usual Attached and then applied locally the Blähglasschicht, this continue by layerwise overspray the thermal insulation element with expanded glass.

The The invention further relates to a wall element based on a Heat-insulating elements, for example thermal insulation element for arrangement on a building facade, with one of the building surface facing Mounting wide area and one of the mounting broad area remote free broad area.

wall elements the type in question are, as described above, known.

In order to further advantageously form a wall element of the type in question, it is provided that the free broad surface is covered by a layer of expanded glass. Expanded glass or foam glass has heat-insulating and, moreover, waterproof properties. As a result of this Such thermal insulation panels are also suitable for the arrangement of moisture applied wall areas, such as in the range of tunnel entrances, swimming pools, wet rooms, etc. In addition, the applied blown glass layer pressure resistant, which also provides a protection of the covered heat insulation element from pressure. In addition, the layer of expanded glass proves to be vapor-tight, non-combustible and acid-resistant, moreover pest-proof. Another advantage of the Blähglasschicht lies in the existing dimensional stability. In addition, the wall element coated with expanded glass has increased thermal insulation properties compared to wall elements, for example in the form of foam plates.

Further Features of the invention are below, also in the figure description, often in their preferred assignment to the subject of the claims 7 or explained to features of further claims. But you can also in an assignment to only individual features of the claim 7 or the respective further claim or in each case independently of Meaning.

In In a preferred embodiment, the expanded glass layer has a layer thickness which is 0.2 times to 2 times the thickness of the heat-insulating element equivalent. The specified numerical bandwidth also closes all Intermediate values, in particular in 1/10 steps, whereby the Layer thickness, for example, also 0.3 times or 1.9 times may correspond to the wall element thickness. Also, the layer thickness for example, 0.8 times or 1.7 times the wall element thickness correspond.

In preferred embodiment are two superposed Blähglasschichten intended. This results in an at least three-layered Structure of the wall element, wherein further more than two Blähglasschichten on the thermal insulation element can be applied.

The preferably two expanded glass layers have different densities. In an arrangement of more as two layers of expanded glass can this also have different densities, with quite two, optionally in layers from each other separate expanded glass layers same or similar Dense may have.

The higher Density of a Blähglasschicht is achieved by applying blown glass bodies lower Volume opposite the inflatable glass bodies to Formation of less dense expanded glass layer. So can continue the inflatable glass body to Formation of the blown glass layer higher Density have a volume that is one-fiftieth to one-half Volume measure of Inflated glass body of Layer correspond to lower density. The blown glass layer low density is in a preferred embodiment directly the free wide area the thermal insulation element is assigned accordingly further sandwiched between the thermal insulation element and the blown glass layer higher Density.

In Further preferred embodiment, the Blähglasschichten are on the broadside the wall element sprayed on, so further preferably when arranged of two layers by immediately successive operations.

The thermal insulation element is designed plate-like, d. H. with a latitudinal and longitudinal extension, the a multiple of the thickness of the heat-insulating element equivalent. Latitude and longitude can hereby in a relationship for example, 1: 1, 1: 2 or 2: 1, moreover, for example, 1: 3 or 3: 1. Also, the provided with the Blähglasschichten thermal insulation element be framed within a framework, which framework of the determination of the heat-insulating element on the building wall, for example, on the building facade serves. Alternatively, the thermal insulation element also in the expanded glass layer anchored mounting bolts or other fixing elements laying down on the building wall be provided.

The thermal insulation element consists in a proposed embodiment of a foam, further example of a melamine resin foam. alternative can the thermal insulation element also from a Baumvollfaservlies or a glass fiber fleece or continue to consist of mineral wool.

below the invention with reference to the accompanying drawings, which only an embodiment represents, closer explained. It shows:

1 a perspective cutout view of a wall element according to the invention;

2 the section according to the line II-II in 1 ;

3 a sectional view according to 2 with an anchored mounting bolt;

Shown and described is a wall element 1 based on a thermal insulation element 2 , The latter consists of a foam material, in particular of a melamine resin foam.

The thermal insulation element 2 is plate-like designed with a thickness d ₁ , which corresponds to a fraction of the length or width of the insulation board. As a result, the heat emanates ment 2 two wide surfaces, namely a mounting wide area 3 with which the wall element 1 a building wall or the like. Is assigned, and a free wide area 4 , which the mounting broad area 3 opposite.

On this free broad area 4 are by spraying two Blähglasschichten 5 and 6 applied. The directly on the free broad area 4 provided Blähglasschicht 5 in this case has a lower density than that on this Ers th Blähglasschicht 5 applied second Blähglasschicht 6 , So are to achieve the first Blähglasschicht 5 A foamed glass 7 larger volume than the Blähglasschicht 6 provided with higher density.

For attachment of the thus designed wall element 1 on, for example, a building facade, as shown in FIG 3 bracket bolts 8th be provided. Such a mounting bolt 8th is in the range of a bolt head 9 in the expanded glass layer 5 and or 6 anchored.

The expanded glass layers 5 and 6 have approximately the same in the illustrated embodiment - perpendicular to the wide surface 4 measured - thicknesses d ₂ and d ₃ , which in the sum of about the thickness d _{1 of} the heat-insulating element 2 correspond.

All disclosed features are (for itself) essential to the invention. In the disclosure of the application will hereby also the disclosure content of the associated / attached priority documents (Copy of the advance notice) fully included, too for the purpose, features of these documents in claims present Registration with.

1

wall element

2

thermal insulation element

3

Mounting broad surface

4

free wide area

5

Blähglasschicht

6

Blähglasschicht

7

A foamed glass

8th

bracket bolts

9

bolt head

d ₁

thickness thermal insulation element

d ₂

thickness Blähglasschicht

d ₃

thickness Blähglasschicht

Claims (21)

Method for producing a thermal insulation panel for placement on a building, for example on a building facade, with a thermal insulation element ( 2 ), one of the building surface facing mounting surface ( 3 ) and one of the mounting broad area ( 3 ) facing away from free broad area ( 4 ), characterized in that the free broad surface ( 4 ) of the thermal insulation element ( 2 ) of a blown glass layer ( 5 . 6 ) is covered. Method according to claim 1 or in particular according thereto, characterized in that the free broad area ( 4 ) of the thermal insulation element ( 2 ) of two superposed Blähglasschichten ( 5 . 6 ) is covered. Method according to one or more of the preceding claims or in particular according thereto, characterized in that the free broad area ( 4 ) of the thermal insulation element ( 2 ) of two superimposed, different densities Blähglasschichten ( 5 . 6 ) is covered. Method according to one or more of the preceding claims or in particular according thereto, characterized in that the expanded glass layer ( 5 ) lower density directly on the thermal insulation element ( 2 ) is applied. Method according to one or more of the preceding claims or in particular according thereto, characterized in that the with the Blähglasschicht ( 5 . 6 ) covered thermal insulation element ( 2 ) is attached to the building surface. Method according to one or more of the preceding claims or in particular according thereto, characterized in that the thermal insulation element ( 2 ) is first attached to the building surface and then the Blähglasschicht ( 5 . 6 ) is applied. Wall element ( 1 ) based on a thermal insulation element ( 2 ), for example, thermal insulation element ( 2 ) for arrangement on a building facade, with a mounting surface facing the building surface ( 3 ) and one of the mounting broad area ( 3 ) facing away from free broad area ( 4 ), characterized in that the free broad area ( 4 ) of a blown glass layer ( 5 . 6 ) is covered. Wall element according to claim 7 or in particular according thereto, characterized in that the expanded glass layer ( 5 . 6 ) has a layer thickness (d ₂ , d ₃ ) which corresponds to 0.2 times to 2 times the thermal insulation element thickness (d ₁ ). Wall element according to one or more of claims 7 to 8 or in particular according thereto, characterized in that two superposed Blähglasschichten ( 5 . 6 ) are provided. Wall element according to one or more of claims 7 to 9 or in particular according thereto characterized in that two expanded glass layers ( 5 . 6 ) of different densities are provided. Wall element according to one or more of claims 7 to 10 or in particular according thereto, characterized in that, in order to obtain a higher density, inflatable glass body ( 7 ) lower volume compared to the blown glass bodies ( 7 ) are provided to form the less high density. Wall element according to one or more of claims 7 to 11 or in particular according thereto, characterized in that the expanded glass layer ( 5 ) lower density immediately of the free broad area ( 4 ) of the thermal insulation element ( 2 ) assigned. Wall element according to one or more of claims 7 to 12 or in particular according thereto, characterized in that the expanded glass layers ( 5 . 6 ) on the broadside ( 4 ) of the wall element are sprayed. Wall element according to one or more of claims 7 to 13 or in particular according thereto, characterized in that the thermal insulation element ( 2 ) is designed plate-like. Wall element according to one or more of claims 7 to 14 or in particular according thereto, characterized in that the thermal insulation element ( 2 ) is in a frame. Wall element according to one or more of claims 7 to 15 or in particular according thereto, characterized in that the thermal insulation element ( 2 ) in the blown glass layer ( 5 . 6 ) anchored mounting bolts ( 8th ) is provided. Wall element according to one or more of claims 7 to 16 or in particular according thereto, characterized in that the thermal insulation element ( 2 ) consists of a foam. Wall element according to one or more of claims 7 to 17 or in particular according thereto, characterized in that the thermal insulation element ( 2 ) consists of a melamine resin foam. Wall element according to one or more of claims 7 to 18 or in particular according thereto, characterized in that the thermal insulation element ( 2 ) consists of a cotton fiber fleece. Wall element according to one or more of claims 7 to 19 or in particular according thereto, characterized in that the thermal insulation element ( 2 ) consists of a glass fiber fleece. Wall element according to one or more of claims 7 to 20 or in particular according thereto, characterized in that the thermal insulation element ( 2 ) consists of mineral wool.