DE102006002281A1 - Method of placing insulation in hollow building block involves forming strips and pushing them into hollow - Google Patents

Abstract

The method of placing an insulation in a hollow building block or tile involves forming rectangular strips of the mineral fibre insulation (7) cut from a web. The web strips have the fibre axes running parallel to the upper faces (9) and side faces and at right angles to the front face. The mineral fibre web, prior to cutting is divided into plates (2) with their longitudinal axis perpendicular to the longitudinal axis of the web. The strips are pushed into the building blocks.

Description

The The invention relates to a method for introducing an insulating material in a cavity of a brick having at least one cavity, in particular a perforated brick in which insulating strips of mineral fibers compressed and inserted into the cavity of the brick, with the insulating strips essentially cuboid are formed and two spaced from each other and have substantially parallel surfaces over two parallel to each other and substantially at right angles to the surfaces aligned side surfaces as well as over aligned substantially perpendicular to the surfaces and the side surfaces faces are connected.

Out In the prior art it is known cavities of a brick, in particular a so-called Hochlochziegels with an insulating material to fill the thermal insulation properties to improve a brick. With such bricks let building walls where an additional thermal barrier on the outside not or only in thinner Copy is necessary to those required by law in thermal insulation regulations predetermined insulation values to achieve. As insulation materials In particular, pourable granules, For example, Perlite used in a simple way in the be poured a relatively small cross section having cavities. The insulation materials be in the cavities hardened, to form a solid bond with the brick.

Further it is known, insulating materials made of hard foam or mineral fibers in the cavities bring. However, this is the introduction of according to the form the cavities trained insulating strips from such insulation materials costly and associated with a high error rate, as the stripes go through the relatively rough interior walls the cavity is damaged or destroyed can be so that only insufficient insulation performance is achieved. The problems with the introduction of insulation strips out of these insulation materials especially by the fact that the insulation strips with respect to the cavities reduced dimensions are formed and introduced.

From the DE 102 17 548 A1 Furthermore, a device for introducing insulating strips of mineral fibers into the cavities of extruded perforated bricks is known. With this device, an insulating strip of mineral fibers is detected and compressed before the insulating strip inserted into a cavity and the device is pulled out of the cavity. In this case, it is provided that the device consists of two mutually parallel plate elements which are movable independently of each other, wherein a plate member has a stop to which the insulation strip of mineral fibers comes to rest. In the intended use of the device, the insulating strip of mineral fibers between the plate elements is arranged, which are then inserted together with the compressed insulating strips of mineral fibers in the cavity. In the cavity, the compression is released so far that the plate elements abut with their outer surfaces on the inner surfaces of the cavity. Subsequently, the first plate member is pulled out of the cavity, while the second, the stop having plate member remains in the cavity. The insulating strip of mineral fibers settles during extraction of the first plate member to the inner surface of the cavity and on the frictional force of the insulating strip mineral fibers remains when pulling the second plate member in the cavity.

With Although this device, it is possible, insulation strips of mineral fibers in cavities of Use perforated bricks, but the preparation of the insulating strips is very consuming and it is only highly compressible insulating materials made of mineral fibers Usable to ensure a secure hold of the insulation strips in the cavities to deliver.

outgoing From this prior art, it is an object of the invention a method to create, with the production of heat and / or soundproofed bricks is greatly simplified and the wall made stones one high heat and / or sound insulation performance and the insulating strips made of mineral fibers quickly and easily without risk of Damage, destruction or loss in the cavities can be used.

The solution this task provides that the insulation strips in such a way a mineral fiber web are cut, that the insulating strips a course of mineral fibers parallel to the surfaces and the side surfaces and at right angles to the faces exhibit.

The inventive method thus provides for the use of insulating strips of mineral fibers, which have a certain course of mineral fibers within the insulation strips and thereby certain strength properties, namely compressive strengths, so that the maintenance of insulation strips of mineral fibers in the cavities sufficiently safe and at the same time the risk of Damage to the Dämmstoffstrei fen is reduced when inserting the insulation strip.

To Another feature of the invention is that the mineral fiber web before cutting the insulating strips transverse to its longitudinal axis is divided into individual mineral fiber plates whose longitudinal axes perpendicular to the longitudinal axis run the mineral fiber web. By producing a mineral fiber web, when a primary fleece to a secondary web Suspended transversely to the direction of transport becomes a predominant one Part of the mineral fibers aligned transversely to the conveying direction. The Alignment of the mineral fibers determines the compressive strength of the mineral fiber web, being a higher one Compressive strength is achieved in the direction of mineral fibers. The Compressive strength of the mineral fiber web can be towards the mineral fibers up to eight times higher be, as transverse to the direction of the mineral fibers. These strength properties are used in the invention.

It is therefore provided in the invention that the insulation strips in the direction of the longitudinal axis the mineral fiber slabs from the mineral fiber slabs ge cut become. The insulating strips thus have a high compressive strength in their longitudinal direction and are otherwise perpendicular to their longitudinal direction compressible, with a high compressibility even with insulating strips given with a high bulk density.

Around the further processing of the insulating strips, especially the insertion in the cavities to simplify is provided according to a further feature of the invention, that the mineral fiber web and / or mineral fiber plates produced therefrom before cutting the insulation strip with regard to the desired material thickness the insulating strip be calibrated. The preparation of insulation strips in the mineral fiber web and / or Mineral fiber board is much easier and more economical than machining single insulating strip. About that In addition, this is a higher quality the insulating strip achieved in terms of their dimensions.

preferably, are grinding the mineral fiber web and / or mineral fiber plates made therefrom, cutting and / or sawing calibrated. This calibration leaves to perform with the necessary accuracy and has regard to the Time required proven.

A Continuing this procedure provides that during calibration resulting loose fiber material sucking and / or blowing away becomes. This feature is used to reduce the air pollution with Mineral fiber material and has over it In addition, the advantage that removed mineral fiber material in the course a recycling can be supplied to the manufacturing process.

Around different sized cavities in bricks to equip can is provided according to a further feature of the invention that the Mineral fiber web and / or mineral fiber plates made therefrom in insulating strips be cut to different width, the arrangement the insulating strip in the mineral fiber web and / or made of mineral fiber boards the arrangement of cavities different width in bricks corresponds. Usually wise Bricks cavities with constant width but two different lengths up, the cavities different length arranged in a row and are equipped as possible simultaneously should, so that the embodiment described above the invention is advantageous. Of course, the inventive method also applied to bricks with more than two cavities in a row become.

A Development of the previously described embodiment of the invention sees before that the insulating strips next to each other alternating with a full width and a half Width of the mineral fiber web and / or made of mineral fiber boards get cut.

The cavities in bricks are not formed cuboid in the rule. It has therefore proved to be advantageous in transition areas from the surfaces to the side surfaces arranged edges of the insulation strip shaping to edit.

The Edges are preferably machined, especially grinding and / or cutting processed. In this training are removed mineral fibers sucked off and fed to the manufacturing process to reduce the mineral fiber load low in the area of this processing station.

In addition can be provided that the edges elasticized, in particular shaping to be whipped. Elasticized edges have the advantage of being adapt better to the contours of the cavities and thus the cavities nearly Completely with insulation filled out become. Not with insulation completed Areas in the cavities that Form thermal bridges can, are essentially avoided.

Preferably Be the edges with one of the required shape of insulation strips corresponding Walk tool gewalkt.

According to a further feature of the invention it is envisaged that the insulating strips are cut to the length of the cavities before and / or prior to insertion into the cavities of the brick.

The Inserting the insulation strips takes place according to the invention in particular in that all insulation strips of a brick simultaneously compressed with a tool and in the cavities of the brick inserted become.

Finally is provided according to a further feature of the invention that the insulating strips in the cavities relaxed and held by their residual stress.

Further Features and advantages of the invention will become apparent from the following Description of the drawing, in the preferred embodiments of devices for implementation the method according to the invention are shown. In the drawing show:

1 a stack of insulating panels in perspective view;

2 a section of a device for the production of insulation strips from the insulation boards according to 1 in perspective view;

3 an insulating strip in perspective view;

4 a first embodiment of a cutting device of the device according to 2 in perspective view;

5 a second embodiment of a cutting device of the device according to 2 in perspective view;

6 several side by side separated insulation strips of different width in perspective view;

7 a first arrangement of a Dämmstoffstreifens in a cavity of a brick in view;

8th a second arrangement of a Dämmstoffstreifens in a cavity of a brick in view;

9 a compression device of the device according to 2 in a first position in a view;

10 the compression device according to 9 in a second position;

11 the compression device according to 9 in a cross section along the section line XI-XI in 9 ;

12 the compression device according to 10 in a cross section along the section line XII-XII in 10 ;

13 the compression device according to 10 in a cross section along the section line XIII-XIII in 10 ;

14 according to the insulating strip 3 in a longitudinal view before and after the passage of the compression device according to the 9 to 13 ;

15 a second embodiment of a compression device in a first position in view;

16 the compression device according to 15 in a second position in view;

17 the insulating strip according to 3 in a view after leaving the compression device according to the 15 and 16 ;

18 an insertion device for insulation strips in a side view in a first position and

19 the insertion device according to 18 in a second position.

In 1 is a stack 1 of several mineral fiber plates arranged one above the other 2 shown. Every mineral fiber plate 2 has two parallel aligned and spaced apart large surfaces 3 on, over parallel longitudinal sides 4 and at right angles to the long sides 4 and also parallel to each other narrow sides 5 connected to each other, so that each mineral fiber plate 2 is formed cuboid. The stack 1 made of mineral fiber boards 2 is on a pallet 6 arranged with the mineral fiber boards 2 is formed the same area.

Every mineral fiber plate 2 is cut from a mineral fiber web, not shown, with the narrow sides 5 in the mineral fiber web in the longitudinal direction, that are aligned running in the conveying direction of the mineral fiber web. As a result, the long sides run 4 perpendicular to the conveying direction of the mineral fiber web, which is produced according to the following manufacturing process:
The mineral fiber web consists of mineral fibers of a silicate melt material, for example of natural or artificial stones and / or Glasses. The starting material, namely the natural or artificial stones and / or the glasses are melted in a smelting unit. A resulting melt is fed to a fiberizing aggregate which, for example in the case of a melt of natural and / or artificial stones, consists of a plurality of rollers rotating at high speed, which are arranged offset one below the other in the direction of the melt flow. When the melt impinges on the rotating rolls, the melt is defibered. The mineral fibers collected in a collecting space are mixed with binder and / or impregnating agent and deposited on a conveying device, for example a conveyor belt, which continuously draws the mineral fibers forming a primary nonwoven web from the collecting chamber. The mineral fibers are aligned in the primary nonwoven web substantially in the conveying direction. The primary nonwoven web is then deposited meandering as a secondary nonwoven web on a downstream conveyor, for which purpose a pendulum device is provided which billows the primary nonwoven web at right angles to the conveying direction of the downstream conveyor as a secondary nonwoven web, so that the original orientation of the mineral fibers in the primary nonwoven web in the conveying direction now perpendicular to the secondary nonwoven web is aligned with the conveying direction of the downstream conveyor.

The Secondary nonwoven web will then continue mechanical process steps, such as compression and pruned the margins before the primary nonwoven web a curing oven supplied becomes, in which the binder connecting the individual mineral fibers hardened becomes.

Subsequently, the mineral fiber web is in the mineral fiber plates 2 subdivided by cuts transversely to the conveying direction or transversely to the longitudinal direction of the mineral fiber web.

In the individual mineral fiber plates 2 Thus, an orientation of the mineral fibers is substantially parallel to the large surfaces 3 and the long sides 4 or at right angles to the narrow sides 5 in front.

By aligning the mineral fibers in the mineral fiber plate 2 or the precursor, namely the mineral fiber web, have the mineral fiber plates 2 different strength properties in the direction of their large body axes. In particular, the compressive strength of mineral fiber boards 2 is determined by the orientation of the mineral fibers, whereby a compressive strength is achieved in parallel to the orientation of the mineral fibers, which is up to eight times higher than the compressive strength at right angles to the orientation of the mineral fibers. This also results in an improved elasticity of the mineral fiber plates 2 perpendicular to the large surfaces 3 compared to the elasticity of the mineral fiber plates 2 right-angled to the narrow sides 5 ,

In the method according to the invention these strength properties for the production of insulating strips 7 used. A corresponding insulating strip 7 is in 3 shown and consists of a cuboid body 8th that has two great surfaces 9 has, which are arranged parallel and spaced from each other. The big surfaces 9 are aligned at right angles to this long sides 10 and at right angles to the long sides 10 and to the surfaces 9 aligned faces 11 connected with each other.

In the insulating strip 7 is a course of mineral fibers 12 provided, which is perpendicular to the end faces 11 is aligned so that the insulation strip 7 perpendicular to its large surfaces 9 and at right angles to its long sides 10 has high compressibility and elasticity.

In 2 is the mineral fiber plate 2 according to 1 shown. From the mineral fiber plate 2 be a variety of insulating strips 7 produced. For this purpose, the mineral fiber board 2 one in 2 schematically illustrated processing station 13 supplied, with the narrow sides 5 the mineral fiber plate 2 in the direction of movement according to an arrow 14 be aligned and moved.

The processing station 13 has a calibration device 15 in the form of a grinding roller 16 on, with a big surface 3 the mineral fiber plate 2 is ground so that a desired degree of material thickness of the mineral fiber plate 2 to be produced insulation strip 7 is achieved. The calibrated mineral fiber plate 2 then passes through a cutting device 17 according to the 2 and 4 from a variety of circular saw blades 18 exists, which are adjacent and spaced apart. With the circular saw blades 18 becomes the mineral fiber plate 2 divided into individual strips in their longitudinal direction.

The processing station 13 also has a walk roller 19 on, with which the individual strips of mineral fiber plate 2 be elasticized. For this purpose, the Walkwalze acts 19 on the big surface 3 the mineral fiber plate 2 and partially dissolves the connection between the individual mineral fibers.

Alternatively to a Walkwalze 19 a milling device can be provided, with which the surface 3 the mineral fiber plate 2 according to the requirements of the insulation to be produced from it fabric strips 7 is milled.

In the 2 not shown in detail is another cutting device, the cuts transverse to the direction of movement of the mineral fiber board 2 performs, so that the individual strips in insulating strips 7 be divided into the same length.

In 5 is an alternative embodiment of a cutting device 17 shown in place of circular saw blades 18 several knives 20 which is attached to a knife bar 21 are attached.

The circular saw blades 18 or the knives 20 can be set at a predetermined distance from each other. But there is also the possibility that the distances between the individual knives 20 or the circular saw blades 18 are adjustable to insulating strips 7 different width of a mineral fiber board 2 to cut. For example, in 6 a number of insulating strips 7 shown with different widths, with the insulating strips 7 different width for correspondingly different widths formed cavities 23 a brick 22 are provided. This can also be the arrangement of the insulation strips 7 in the mineral fiber plate 2 according to the further processing of the insulating strips 7 be provided, for example, two narrow insulation strips 7 between two wide insulating strips 7 are arranged as in 6 is shown.

In the 7 and 8th is a part of a brick 22 with a cavity 23 shown in which an insulating strip 7 is arranged. It can be seen that the insulating strip 7 the cavity 23 almost completely fills, but in the area between the large surfaces 3 of the insulating strip 7 and inner wall surfaces of the cavity 23 unfilled areas 24 according to 7 remain.

8th shows an embodiment in which the unfilled areas 24 between the inner wall surfaces of the cavity 23 and the long sides 10 of the insulating strip 7 are arranged. To those described above and in the 7 to 8th illustrated discontinuities in the field of insulation of a corresponding brick 22 to be completed, reference is made to the following description of an advantageous embodiment of the invention.

In the 9 and 10 is a walker 25 with two walk rollers 19 illustrated, wherein each Walkwalze 19 areas 26 having enlarged cross-section. The areas 26 Both Walkrollzen 19 are arranged opposite one another, wherein the distance between two adjacently arranged areas 26 almost the width of an insulating strip 7 equivalent.

9 shows the walker 25 out of engagement, whereas 10 the walker 25 during the walk. Here, the areas walk 26 the insulating strips 7 in the area of their long sides 10 , so that here the binding of the mineral fibers is loosened, whereby a subsequent further processing of the insulating strips 7 is possible in the insulation strips 7 get a shape that allows the insulating strips 7 such in the cavities 23 a brick 22 to insert that these cavities 23 completely, ie without training of areas 24 fill out.

In the 11 to 13 is the intervention of the Walkwalzen 19 in an insulating strip 7 shown. 14 shows an insulating strip 7 after passing through the walker 25 , where in the upper part of the 14 the insulating strip 7 without change of shape and in the lower part of the 14 is shown after the change in shape. It can be seen that the edge regions of the insulating strip 7 shaping the transition area between the large surfaces 9 and the long sides 10 round.

In the 15 to 17 is this shape with a corresponding device 27 shown, wherein the device 27 on the corner areas 28 the insulating strip 7 acting stamps 29 having, which at their the Dämmstoffstreifen 7 facing surfaces circular arc portion-shaped surfaces 30 having. The stamps 29 can be part of the Walkwalzen 19 in the fields of 26 be.

15 shows the position of the stamp 29 before processing the insulating strips 7 , while 16 the stamps 29 in the engaged position.

The finished shaped insulating strip 7 is in 17 shown. It can be seen that the corner areas 28 according to 15 at the finished insulating strip 7 rounded are formed.

Finally, the show 18 and 19 schematically a device 31 for inserting insulating strips 7 in the cavities 23 of the brick 22 , The device 31 consists of a T-shaped carrier 32 , on which several gripping arms 33 are arranged. Every gripper arm 33 consists of two mutually variable in their distance holding elements 34 that go along the carrier 32 are displaceable. Between two holding elements 34 is a recording room 35 formed, the inclusion of an insulating strip 7 serves. The holding elements 34 can be moved towards each other be that one in the recording room 35 absorbed insulation strip 7 is compressed.

18 shows the device 31 just before the inclusion of four insulating strips 7 in the four recording rooms 35 , In 19 they are in the reception rooms 35 compressed arranged insulating strips 7 shown, wherein the retaining elements 34 with the compressed insulating strips 7 in the cavities 23 of the brick 22 are inserted.

Claims (15)

Method for introducing an insulating material into a cavity of a brick having at least one cavity, in particular a perforated brick, are compressed in the insulating strips of mineral fibers and inserted into the cavity of the brick, wherein the insulating strips are formed substantially cuboid and two spaced from each other and substantially have parallel surfaces, which are connected via two mutually parallel and oriented substantially perpendicular to the surfaces side surfaces and aligned substantially at right angles to the surfaces and the side surfaces end faces, characterized in that the insulating strips ( 7 ) are cut from a mineral fiber web such that the insulating strips ( 7 ) a course of mineral fibers ( 12 ) parallel to the surfaces ( 9 ) and the side surfaces ( 10 ) and at right angles to the end faces ( 11 ) exhibit. A method according to claim 1, characterized in that the mineral fiber web before cutting the insulating strips ( 7 ) transversely to its longitudinal axis into individual mineral fiber plates ( 2 ), whose longitudinal axes extend at right angles to the longitudinal axis of the mineral fiber web. Method according to claim 2, characterized in that the insulating strips ( 7 ) in the direction of the longitudinal axis of the mineral fiber plates ( 2 ) from the mineral fiber plates ( 2 ) get cut. A method according to claim 1, characterized in that the mineral fiber web and / or mineral fiber plates produced therefrom ( 2 ) before cutting the insulating strips ( 7 ) with regard to the desired material thickness of the insulating strips ( 7 ) are calibrated. A method according to claim 4, characterized in that the mineral fiber web and / or mineral fiber boards produced therefrom ( 2 ) are calibrated for grinding, cutting and / or sawing. Method according to claim 5, characterized in that sucking loose fiber material resulting from the calibration and / or blowing away. A method according to claim 1, characterized in that the mineral fiber web and / or mineral fiber plates produced therefrom ( 2 ) in insulating strips ( 7 ) of different widths, the arrangement of the insulating strips ( 7 ) in the mineral fiber web and / or mineral fiber boards produced therefrom ( 2 ) the arrangement of cavities ( 23 ) of different widths in bricks ( 22 ) corresponds. Method according to claim 1, characterized in that the insulating strips ( 7 ) side by side alternately with a full width and a half width of the mineral fiber web and / or mineral fiber boards produced therefrom ( 2 ) get cut. A method according to claim 1, characterized in that in transition areas of the surfaces ( 9 ) to the side surfaces ( 10 ) arranged edges of the insulating strips ( 7 ) are edited. Method according to claim 9, characterized in that that the edges are machined, in particular grinding and / or cutting or sawed become. Method according to claim 9, characterized in that that the edges are elasticized, in particular shaped shaping. A method according to claim 10, characterized in that the edges with one of the required shape of the insulating strips ( 7 ) corresponding Walk tool be gewalkt. Method according to claim 1, characterized in that the insulating strips ( 7 ) finally and / or before insertion into the cavities ( 23 ) of the brick ( 22 ) on the length of the cavities ( 23 ) are cut to length. A method according to claim 1, characterized in that all insulating strips ( 7 ) of a brick ( 22 ) compressed simultaneously with a tool and into the cavities ( 23 ) of the brick ( 22 ). A method according to claim 14, characterized in that the insulating strips ( 7 ) in the cavities ( 23 ) and held by their residual stress.