DE10008332C1 - Insulation material for clamping installation between boundaries - Google Patents

Abstract

An insulating material, especially a line of insulating material (10), is used for jamming between delimiting structures. Said insulating material comprises at least one first section (14) extending in the longitudinal direction of the insulating material, whose width corresponds essentially to the thickness of the insulating material; and at least two second sections extending in the longitudinal direction of the insulating material, whose width is greater than that of the first sections. The at least two second sections (16) have a fold-type cut (18) which extends in the longitudinal direction of the insulating material and which does not completely separate the second sections (16). The at least one first section (14) can be separated from an adjacent first section (14) or a second section (16) by means of a perforation line extending in the longitudinal direction or a separating cut (16).

Description

Field of the Invention

The invention relates to an insulating material, in particular an insulation sheet for clamping installation between Limitations.

State of the art

Both for on-site assembly in the outbuilding as well when insulating floor ceilings or both Rafter insulation becomes standardizable System solutions preferred. This should be done with a small Number of products a wide range of applications be covered.

When insulating wall and ceiling elements, the Insulation materials introduced into compartments by a Column grid are limited. After inserting the The wall or ceiling element becomes insulation in the compartments from the front facing the user with plates covered.

Due to the individual structural conditions compartments in wall and ceiling elements different compartment widths and / or compartment lengths have. In this area, the state of the art Insulation material with a special cut with regard to the width as well as length get to optimal  To be able to ensure insulation properties. If Insulation sections with excessive oversize in compartments are pressed in, pinch joints are formed, which the Significantly reduce insulation properties. After the appearance from pinch joints in the compartment it can get through Steam convection can cause condensation damage.

Various attempts have been made in the prior art undertaken to insert insulation materials to simplify between rafters.

In German utility model DE 297 00 232 U1 there is one Insulation board described, which consist of two interconnected Insulation board sections that are articulated with each other are connected. By providing a hinge, the made of tough foam, in particular polystyrene foam, existing insulation board is inserted between rafters, the compression of the insulation board during the clamping installation not just from the edge areas of the insulation board must be included.

The international patent application WO 98/42930 describes an insulation board with a in the longitudinal direction Insulation direction running folding cut near the lateral longitudinal edges, which the folding of each Edge area of the insulation board allows, so that after Fold the fiber direction by 90 ° in the side areas is rotated. By contacting the rafters end faces of the insulation board a strip is attached in which the fiber direction is rotated 90 °, this strip has a higher elasticity, so that greater tolerances in terms of the distance between two neighboring rafters through one and the same Pre-assembled material can be added.

In the German utility model 298 23 549 a Mineral wool insulation board proposed for  Insulate between rafters and wooden stud structures is provided. The insulation board consists of a meandering folded insulation material, resulting in a high elastic compressibility of the insulation board results.

DE 93 14 719 U1 describes an insulation board made of tough and hard Foam plastic for clamping installation between rafters. Cavities enclosed in the foam plastic of the insulation board are with a kinked or crumpled surface provided so that the plate body at least in one Direction elastically compressible parallel to the top surfaces is. By kinking or crumpling the surface of the Cavities form hinge lines that create a light, enable bellows-like indentation of the cavities, from which the elastic compressibility of the insulation board results. DE 93 14 719 U1 represents the closest one State of the art.

Presentation of the invention

The invention is based on the object Insulation material for clamping installation between boundaries propose that can be used as variably as possible.

This task is achieved with an insulation material Features of claim 1 solved.

The invention is based on the idea of a Insulation material, especially an insulation sheet, so to design them first and second sections having. The first sections as well as the second sections are separated by cuts or perforations separated that in the longitudinal direction of the insulation material run. The first section has a width that in corresponds essentially to the thickness of the insulation sheet, while the at least two second sections have a width, which is greater than the thickness of the insulation material.  

In addition, the at least two second sections have a longitudinal folding cut that the second section not completely severed. The first In contrast, the second section is about a Perforation line or a separating cut connected so that the first section of the adjacent second Section is easily removable.

The limits can be implemented in any way, e.g. B. as a wooden frame construction with all-round enclosed Divisions or just in parallel to each other trimmed borders made of wood, metal or another Material.  

In that the first section has a width which in corresponds essentially to the thickness of the insulation material, can be removed from the second section the first section used arbitrarily become. So it is possible, for example, the first Insert section rotated by 90 °, d. H. by the first Section with vertical grain direction is installed. This Rotation by 90 ° is possible because the first section is wide has, which is essentially the thickness of the insulation web corresponds. Thus, the first section has one Cut a square perpendicular to the longitudinal extension Cross section and can be used rotated by 90 °.

When the insulation strip forming the first section Inserted 90 ° rotated in a compartment, the extends Width of the insulation strip in the direction of the compartment depth. This leads to compartments with the first section very different compartment widths can be insulated, because due to the rotation before installation, the insulation material turns around can compress up to 70% without the Springback properties suffer significantly. The The reason for the high compressibility is that Insulation materials are generally relatively high in the direction of the fibers Stiffness perpendicular to the prevailing However, the direction of the fibers can be clearly compressed. In the Glass fiber manufacturing using a chute the glass fibers settled in layers on a conveyor from, so that insulation materials produced in this way have a predominant fiber direction that is parallel to the main levels. This applies in the same way to Insulation sheets as well as insulation panels that are in the This is the only way to manufacture the insulation web distinguish that the continuously manufactured and removed fiber material in sheets of a suitable size is divided. Under the above turning of the Insulation material before installation in a compartment should be in  The following can therefore be understood that this is so for installation is arranged that the main direction of fiber extension lies in a plane parallel to the compartment depth. It is formed thus standing fibers that extend in the direction of the compartment depth extend.

The second sections contribute to one in the same way variable use of insulation materials. By the The folding cut can be provided Install insulation material easily and without any gaps. Depending on the compartment width or rafter spacing, you can do this individual second sections, a second section with a associated first section, two side by side arranged second sections or a combination of the above arrangements of sections with one around 90 ° rotated first section can be used. Thus leaves a very high variability in the clamping installation of the insulation material according to the invention between limits achieve.

Another aspect of the advantageous use of a Folding cut lies in the fact that insulation materials are also common be used between double-T beams. Because of the The flap cut provides installation-obstructing flanges a valuable contribution in that insulation material without locally exceeding the maximum compressibility can be used between the double-T beams.

Preferred embodiments are by the rest Labeled claims.

According to a preferred embodiment, the Folding cuts in the middle in relation to the width of the second Sections. This enables a symmetrical opening of the second sections.  

The insulation material preferably further comprises one or several perforations that are transverse to the longitudinal extension of the Insulation material, especially the insulation sheet, run. By providing the transverse Perforation allows the required size to be cut further reduce by separating the insulation material sections of the perforation or perforations arise that correspond to the common floor height.

According to a preferred embodiment, this comprises Insulation material also has an integrated trickle protection in the form of a fiber-binding coating on the top the insulation sheet. This makes PE films unnecessary, so that no more water bags can occur. By the Coating the insulation materials hydrophobic, the insulation materials but still remain vapor permeable, the additional operation of attaching a barrier film save on.

The thickness of the insulation material is preferably such set that a simple location to Sound box damping is suitable and a double layer Thermal insulation is suitable. This has the advantage that everyone Insulation types with only one insulation material of a given Strength can be realized. This fulfills the wish System building materials in the professional world.

Brief description of the drawings

The invention is explained below purely by way of example using the attached figures, in which:

Fig. 1 is a schematic diagram showing an example of the insulation material of the invention shows;

Fig. 2 is a schematic illustration showing various examples of the variable application of the insulating material according to the invention in the clamping installation between boundaries; and

Fig. 3 is a schematic representation showing the use of the insulating material according to the invention in the thermal insulation of a floor ceiling;

Fig. 4 is a schematic representation illustrating the introduction of the insulation material between the web supports.

Ways of Carrying Out the Invention

In the following exemplary embodiments of the invention are similar or the same elements with the same Reference characters are referred to.

An embodiment of the insulation material according to the invention is shown in Fig. 1. The exemplary embodiment explained in more detail with reference to FIG. 1 represents an insulating material web that is in the rolled-out state. In the same way, however, the following explanations can also be applied to insulation boards, although insulation boards are provided with a shorter length and do not have the transverse perforation area shown in the insulation web according to FIG. 1.

The insulation material shown in Fig. 1 is generally designated by reference number 10 and has a length 2 L, which corresponds essentially to a double room height L. In order to ensure that the insulation material is jammed, half a length L is provided, which exceeds the maximum room height by approx. 1 cm.

The insulation material 10 preferably consists of glass wool and has a bulk density of 14 to 20 kg / m ³ and preferably of 14 to 17 kg / m ³ .

In the middle with respect to the longitudinal extent of the insulating material 10 , a perforation 12 running transversely to the longitudinal direction is provided, which is produced in the production process with a pair of guillotine shears and at the installation site, ie on the construction site, conveniently and without aids cutting the insulating material 10 into two sections with a length L enables. As a result, the format cut is omitted for common floor heights when using the insulating material 10 for wall insulation.

In addition, the insulating material 10 is made up of several sections, each of which extends in the longitudinal direction of the insulating material 10 and will be explained in more detail below. The core of the insulating material 10 is a first section 14 , which is connected via separating cuts 15 or alternatively perforations to second sections 16 , which will be explained in detail later. In the present example, only a single first section 14 is arranged between the second sections 16 , but two first sections with identical dimensions can also be arranged next to one another in the same way.

The peculiarity of the first sections is that their width B corresponds to the thickness D of the insulating material within the usual manufacturing tolerances. In the form of illustration shown in FIG. 1, a square cross section is thus formed in a cut perpendicular to the longitudinal extent of the insulating material 10 .

Adjacent to the first section 14 are the second sections 16 , the width of which is much larger than the thickness of the insulating material. Arranged centrally with respect to the width of the second sections 16 is a folding cut 18 , which extends from the top 20 of the insulating material only into the insulating material to such an extent that the folding of the insulating material shown in more detail in FIGS . 3 and 4 is possible repeated folding of the second sections 16, however, does not lead to a separation of the two halves.

The thickness D of the insulating material is preferably chosen so that the insulating material 10 can also be used for resonance damping, whereas the higher thicknesses of the insulating material layer required for thermal insulation can be achieved by superimposing several layers. The thickness D of the insulating material can therefore be 160, 180 or 200 mm as common examples and the width B of the first section is accordingly 160, 180 or 200 mm.

The insulation web 10 is produced in a customary manner using a chute for collecting the fiberized material, conveying the continuously produced insulation web through a hardening furnace and then trimming the edges to size and applying the separating, folding cuts and perforation lines running in the longitudinal and transverse directions. The cutting cuts can be made using circular saws, especially diamond-tipped saws with a negative cutting angle. These circular saws are arranged in a line and produce separating cuts running in the longitudinal direction of the insulation product. Devices that trim the insulation material with the help of high-pressure water jets can also be used for edge trimming. If instead of the separating cuts 16 between the first section 14 and the second sections 16 perforations are to be produced, then these too can be produced by means of devices permanently installed on the line and running with the generated insulation material webs. The transverse perforations 12 are preferably created with specially designed guillotine shears.

The insulating material web shown in FIG. 1 is wound up into a roll as part of the manufacturing process and provided with a film packaging.

In FIG. 2, an example of application for the introduction of the insulating material between arranged in different distance limits is illustrated.

As can be seen from FIG. 2, insulating materials are to be introduced between the limits 22 a, 22 b, 22 c and 22 d. There is a distance b ₁ between the boundaries 22 a and 22 b, which is smaller than the width B and therefore also the thickness D of a first section 14 due to the square cross-sectional shape. In order to be able to fill the compartment to be insulated between the boundaries 22 a, 22 b with the pre-assembled insulating material 10 without a format cut, the first strip 14 is rotated by 90 ° so that it has the orientation shown in FIG. 2 above. As already explained above, the insulation material has a significantly higher compressibility in the direction of the insulation thickness D than in the direction of the insulation width B. Therefore, it is also possible to compress the insulation strip 14 turned by 90 ° in the direction of arrow F to such an extent that it between the limits 22 a and 22 b at a distance b ₁ from each other. The compressed first section 14 can then be inserted between the limits 22 a and 22 b.

A format cut is at most still necessary in relation to the length, which extends perpendicular to the plane of the drawing in FIG. 2. Since the width of the first section corresponds to the thickness of the insulation web, the available space between the limits 22 a and 22 b is also completely filled with respect to the height.

As can be seen from Fig. 2, the distance between the limits 22 b and 22 c is larger and between the limits 22 c and 22 d further increased. Depending on the existing distance between adjacent boundaries, between which an insulating material is to be installed by clamping, a selection can be made with regard to the compilation of one or more strips of insulation material, which overall allow the greatest possible variability of different distances between adjacent boundaries. In the present example, a second section 16 is introduced by clamping between the borders 22 b and 22 c, the second strip 16 first being folded with the aid of the folding section 18 , as shown in FIG. 2, the insulating material strip already being between the borders 22 b and 22 c is inserted. Finally, the section 16 inserted as in FIG. 2 is pressed in the direction of the arrow H against the rear boundary 24 , as a result of which the folding cut 18 closes and the insulating material is firmly clamped between the boundaries 22 b and 22 c.

In the example of a larger distance between the boundaries 22 c and 22 d, also shown in FIG. 2, an edge strip with the width b ₂ remains to be filled after the introduction of the second section 16 . Since this edge strip is considerably narrower than the width B or thickness D corresponds to a first section 14 , the first section 14 is rotated again, as explained in the preceding example of the insulation between the boundaries 22 a and 22 b, and in the direction of the arrow F. compressed the required dimension. After the introduction of the section 14 between the section 16 and the boundary 22 d, the two insulating material sections 14 and 16 are held in a clamped manner by the elastic springback forces.

In FIG. 2, only some possible applications are presented. For example, there may also be the case that the distance between the limits 22 c and 22 d is larger than shown, so that the first section 14 is introduced without first rotating through 90 °, since after the introduction of the second section 16 the remaining one Section b _{2 is} only slightly smaller than the width B of a first section 14 . For an even greater distance between adjacent boundaries, however, a plurality of first sections can also be introduced next to one another, rotated through 90 ° or also with the same fiber direction as the second section, or two or more second sections can also be installed by clamping next to one another.

In Fig. 2 only a section through a wall or ceiling element is shown, but it should be noted at this point that lintel and parapet areas are present in particular in the case of wall elements in the window and door area which require special format cuts. For example, a crosscut must often be made in the parapet area, since the predefined length L of the insulating material 10 corresponds to the predefined floor height, which exceeds the parapet height. Likewise, adjustments in the lintel area are necessary, with horizontal installation also being possible here, ie the use of first or second sections which are inserted into the compartments in the lintel area such that the longitudinal extent corresponding to the length L shown in FIG. 1 after installation and the assembly of the relevant component comes to rest in the horizontal direction.

In the example shown in FIG. 3, a simple position of the insulating material 10 was used. In the area of ceiling insulation, simple layers are often used as sound box insulation, while double layers are used for effective thermal insulation. FIG. 3 shows such an example of a ceiling insulation between the boundaries 22 e and 22 f, a second insulation layer 10 b being arranged over a first insulation layer 10 a. The insulating layers 10 a and 10 b may be constructed from the individual variable, the existing sections of the insulating material 10 in the manner explained with reference to FIG. 2 ways.

In the insulation of a floor ceiling shown in Fig. 3, an integrated trickle protection can be provided, in which the product is formed so that the upper fiber areas are provided with a layer 30 , which produce a better fiber composite and also cause hydrophobization. Such a layer 30 can be brought about by spraying on a suitable finish. By using such a layer, a water-permeable, integrated trickle protection is generated, so that the use of a film to be attached over the insulation layer is omitted.

As has already been explained with reference to FIG. 2, the second sections 16 can be fitted between the boundaries without any squish joints due to the folding section 18 . This is particularly advantageous when using web girders, such as double-T girders, as is illustrated with reference to FIG. 4. In FIG. 4, two joists are shown 22 g and 22 h, between which an insulating strip is clampingly fitted. In the present case, this is carried out using a second section 14 , which is first folded with the aid of the folding cut 18 , is introduced into the space between the web supports 22 g and 22 h and is then brought back into an extended starting position by pressing in the direction of arrow H. becomes. The folding cut 18 is arranged centrally in FIG. 4 within the insulation web section 14 , but can also be arranged asymmetrically, two sections of different width adjoining the folding cut 18 .

The insulating material according to the invention is suitable for both on-site assembly in the finishing house as well as for the insulation of Floor ceilings, both a sound box insulation as thermal insulation can also be carried out. Farther can provide the insulation with integrated trickle protection be so that no separate film cover is required. By providing a folding cut, the  Fit the clamping felt between the boundaries and without any creep joints due to the registration strip referred to as the first section of the insulation material can be adjusted in compartments different widths with a width tolerance of about 20% can be realized. The high variability decreased decisive the required format cut, so that Predefined insulation in less time and with less Cuttings can be carried out because of not otherwise usable waste of a separate Disposal must be supplied, can also be Reduce discarded waste.

Claims (6)

1. Insulation material, in particular insulation sheet ( 10 ) for clamping installation between limits ( 22 a to 22 h) with

• - At least one, in the longitudinal direction of the insulation material, first section ( 14 ), which has a width (B) which corresponds essentially to the thickness (D) of the insulation material, and
• - at least two second sections ( 16 ) running in the longitudinal direction of the insulating material, the width of which is greater than that of the at least first section ( 14 ); in which
• - The at least two second sections ( 16 ) have a folding cut ( 18 ) running in the longitudinal direction of the insulation material, which does not completely cut through the second sections; and
• - The at least one first section ( 14 ) can be separated from an adjacent first section ( 14 ) or second section ( 16 ) via a longitudinal perforation line ( 15 ) or a separating cut.

2. Insulation material according to claim 1, characterized in that the folding cuts ( 18 ) extend centrally with respect to the width of the second sections ( 16 ). 3. Insulation material according to one of the preceding claims, further comprising a perforation ( 12 ) extending transversely to the longitudinal extent of the insulation material through the insulation material. 4. Insulating material according to one of the preceding claims, further comprising an integrated trickle protection in the form of a fiber-binding coating on the top ( 20 ) of the insulating material ( 10 ). 5. Insulation material according to one of the preceding Claims, characterized in that the thickness (D) of the Insulation material is set so that a simple Location is suitable for sound box insulation and a Double layer of insulation material for thermal insulation suitable is. 6. Insulation material according to one of the preceding claims, wherein
the insulation material consists of glass wool; and
the glass wool has a bulk density between 14 and 20 kg / m ³ and preferably between 14 and 17 kg / m ³ .