DE202011051264U1 - Exterior insulation device - Google Patents

Abstract

Thermal insulation composite device for insulating a wall (10) comprising at least one insulating material base body (11), with webs (13) aligned parallel to one another and spaced apart from one another on the front side (12) of the insulating material base body (11) to form at least one receiving area (14) for receiving a A plurality of straps (15) are arranged and the straps (15) are arranged in the receiving area (14) at least essentially cohesively on the front side (12) of the insulation base body (11) between the webs (15), characterized in that the insulation base body (11) has a bulk density greater than or equal to 14 kg / m3 and the aprons (15) have a support width between 18 and 50 mm.

Description

The present invention relates to a thermal insulation composite device for insulating a wall comprising at least one insulating base body, wherein on the front side of the Dämmstoffgrundkörpers parallel aligned and spaced apart webs to form at least one receiving area for guided recording a plurality of straps are arranged and the straps in the receiving area at least in Substantially cohesively arranged on the front side of the insulating base body between the webs.

Such devices and arrangements are used in particular in the subsequent insulation of external walls of existing buildings. On the outer walls of insulating body first lot and horizontal are glued, so that the webs form a system of horizontal and mutually parallel lines on the front sides of the insulation boards. The insulation boards are additionally secured to the building wall by means of impact or heat bridge-free screw anchors. On the front sides of the insulation base are in the receiving areas between the webs straps, preferably applied by gluing. The webs form a kind of joint control system, d. H. The straps are aligned flush by the protruding ridges on the front of the insulation panels in the horizontal. Such joint control systems have been marketed for several years by various manufacturers in the trade.

Finally, the joints defined by the webs are grouted between the straps. The overall visual impression of a building wall insulated in this way thus essentially corresponds to that of a conventional building wall, for example that of a bricked house wall.

Another thermal insulation composite system is for example from the document DE 20 2007 017 751 U1 known. This known composite thermal insulation system consists of prefabricated thermal insulation elements, each consisting of an insulating body and Verblendelementen, which are glued to the insulating body. As facing elements come in particular Klinkerriemchen of baked clay used whose dimensions are small in relation to the dimensions of the insulating body.

The known thermal insulation systems have the disadvantage that the dimensions of the Klinkerriemchen used are small in relation to the dimensions of the Dämmstoffkörpers. In particular, the thickness of the straps is usually limited to a thickness of 9 to 17 mm, otherwise there is a risk of detachment of the straps from the insulating body, in particular by the structural failure of the insulating body surface due to the increased dead weight. Particular attention is also paid to the fire protection and the resistance of insulated with such thermal insulation composite walls against the action of high temperatures. Especially in case of fire, despite the action of high temperatures, even in heat and fire over a longer period of time, the peeling of the straps must be avoided to protect the underlying insulating body from direct fire and thus counteract an uncontrolled spread of the fire.

It is therefore an object of the present invention to provide a heat insulation composite high robustness, which ensures a reliable attachment of straps, especially large-sized straps on the insulating base body.

The object is achieved by the thermal insulation composite device with the features mentioned above in that the insulating base has a density greater than or equal to 14 kg / m ³ and the straps have a support width between 18 and 50 mm. Particularly preferably, the insulation base has a density in the range between 14 kg / m ³ and 25 kg / m ³ . A raw density of 14 kg / m ³ and more offers the advantage that both the transverse tensile strength of the insulating base body and the adhesive tensile strengths are significantly increased. Thus, the transverse tensile strength is of the order of about 150 kPa, while the adhesive tensile strengths are typically of the order of 0.15-0.24 N / mm ² . It is therefore possible to bond the straps directly, for example by means of an adhesive mortar, with the front sides of the insulation base body. The application of a reinforcement on the front side of the insulating base body before the application of the straps can thus be dispensed with. Even straps with a thickness greater than or equal to 18 mm, which have an increased weight due to the material thickness, can be arranged directly on the front side of the insulating base body, so that even with this comparatively large contact width of the straps, reliably avoiding detachment of the straps even in the event of fire becomes. Of course, it is additionally possible to further increase the mechanical and thermal resilience of the connection between the straps and the insulating body by attaching a reinforcement between the insulating base bodies and the straps.

By using straps with a support width between 18 and 50 mm, there is another advantage. Due to the support width between 18 and 50 mm at the same time the joint depth and thus the amount of grout can be brought into the joints significantly increased. The joint depth results from the contact width of the straps minus the web height. In other words, by using the straps with the aforementioned overlay width, the joint depth at the same time as the known systems is significantly increased. This has a particularly advantageous effect on the robustness of the thermal insulation composite device according to the invention. Thus, on the one hand overall, the resistance of the thermal insulation composite device, for example, against weather influences, such as humidity changes, rain, snow, frost and heat, significantly increased. On the other hand, the large joint depth has a positive effect on the resistance of the thermal insulation composite device with respect to the action of fire. Another advantage in the use of straps with a contact width or thickness between 18 and 50 mm is that the waste produced during production from a solid brick is significantly reduced. Due to the larger contact width and the proportion of fracture or waste material is significantly reduced in the production of the straps. The graining of the solid stones, from which the aprons are usually cut by means of a double knife, extends up to 5 mm from the solid surface into the solid stone, thus weakening the mechanical structure of the strips cut therefrom. The support width according to the invention of the straps between 18 and 50 mm further requires that the graining extending in the strapping occupies only a small part in relation to the total material width of the straps. Consequently, the mechanical structure of the strap when cutting out of the solid brick is only slightly weakened and so reduces the committee to a minimum. An expedient embodiment of the invention is characterized in that the insulating base body has a profiled edge region for the positive lateral connection of a plurality of insulation base body together. Thus, the insulation body can be largely flush with each other without gaps. This offers the advantage that arbitrarily large surfaces can be provided by juxtaposing a plurality of insulation base body with the thermal insulation composite according to the invention.

A preferred embodiment of the invention is characterized in that the insulating base consists at least substantially of expanded polystyrene. Expanded polystyrene combines very good thermal insulation properties with a low dead weight.

According to a further preferred embodiment of the invention, the straps have a length between 15 cm and 100 cm and a height between 3.5 cm and 30 cm. The attachment of straps of the dimensions mentioned offers, in addition to optical advantages and the ability to use large-sized straps for clothing, further the delay that the surface to be grouted is considerably reduced compared to the use of strappy small dimensions. This not only leads to a saving in working time, which is needed for grouting, but also to a significantly reduced consumption of grouting material. Furthermore, the larger dimensions of the straps have a positive effect on the fire protection properties of the thermal insulation composite according to the invention due to the reduced total joint surface.

A further advantageous embodiment of the invention is characterized in that the straps are impregnated with a hydrophobing agent. The water repellents are already applied in the factory. Alternatively, however, the water repellents can also be applied subsequently. By means of the hydrophobing agent, the water absorption of the straps can be adjusted and adapted over a wide range to the given requirements.

According to a further preferred embodiment, the straps are set up and designed such that the water absorption of the straps is 0.4% to 30%. The water absorption capacity of the straps in the stated range between 0.4% and 30% leads to an improved adhesion of the straps on the insulating base body and thus overall to a greater robustness of the entire thermal insulation composite device. Particularly preferably, the straps are set up and designed such that the water absorption of the straps is greater than or equal to 6%. A water absorption greater than or equal to 6% favors the adhesion of the aprons, for example by means of an adhesive mortar, arranged on the insulating base bodies straps.

A further advantageous embodiment of the invention is characterized in that the straps are designed as brick clinker, concrete or extruded straps. While the brick and / or clinker strips comprise clay as the basic material, the concrete slips as a basic material have concrete or concrete components. This offers the advantage that the surface formed by the straps and visible from the outside corresponds optically to a conventional clinker facade or a brick-clad façade or a building wall. In addition, the brick or tile Clinker straps provide reliable protection against external influences. These improved fire protection properties have a particularly advantageous effect on securing the door and lintel areas of a building insulated with the thermal insulation composite device according to the invention. Especially these areas are subjected to a strong fire flame in a fire, as the flames from the building inside through the window or door opening in the lintel area in the open and beat this area is thus exposed to a particularly high thermal load.

According to a further preferred embodiment of the invention, the straps are ceramic. In addition to the special visual impression ceramic straps have the advantage that they are easy to clean. On the other hand, ceramic straps are absolutely frost-resistant and particularly resistant to heat and / or fire.

A further preferred embodiment of the invention is characterized in that a reinforcement is arranged between the straps and the front side of the insulation base body. The reinforcement offers the advantage of increased mechanical strength of the insulating base body.

According to the invention, a plurality of such thermal insulation composite devices are arranged for insulating a wall or a wall section on the wall or the wall section. To avoid repetition in this context, reference is made to the advantages of the inventive thermal insulation composite device explained above.

A further advantageous embodiment of the invention is characterized in that the insulating base body are at least substantially cohesively connected to the wall or the wall portion. The material bond is preferably achieved by an adhesive mortar applied on the back of the insulating base body. By means of the adhesive mortar unevenness of the wall or the wall section can be compensated to a certain extent. Furthermore, by means of back-side bonding of the insulating base body to the wall or the wall section, large areas can be quickly and effectively equipped with the thermal insulation composite device according to the invention. Another advantage consists in a substantially full-surface bonding, which ensures a high reliability of the connection between the insulating base body and the wall or the wall sections.

According to a further preferred embodiment of the invention, the insulating base body by means of fastening means are arranged non-positively on the wall. In this way it is possible to fix the insulating elements in addition to the wall or the wall section and to secure against unwanted loosening.

Further preferred and / or useful features and embodiments of the invention will become apparent from the dependent claims and the description. Particularly preferred embodiments will be explained in more detail with reference to the accompanying drawings. In the drawing shows

1 a perspective view of the arranged on a wall thermal insulation composite device,

2 a Dämmstoffgrundkörper in plan view and cross-sectional view, and

3 a cross-sectional view of the arranged on a wall or a wall portion thermal insulation composite device.

1 shows an example of a perspective view of a wall 10 or a wall section 10 arranged inventive thermal insulation composite device. The thermal insulation composite device comprises a plurality of insulating base body 11 , On the front side 12 the insulating material body 11 are as in the plan view and the cross-sectional view according to 2 shown as an example, bars 13 arranged. The bridges 13 are spaced from each other and aligned parallel to each other. Preferably, the web height is about 4 mm. Two adjacent bridges each 13 each form a receiving area 14 for a plurality of straps 15 , The straps are in the receiving area 14 between the bridges 13 arranged. The webs form 13 a guide means with the help of the straps 15 are aligned horizontally. In other words, the webs form 13 a kind of joint control system by means of which the straps 15 evenly aligned and arranged horizontally in a particularly simple manner. Preferably, the distance between each two adjacent webs 13 Corresponding to the height of the straps 15 formed so that the straps 15 under partial positive connection between the webs 13 are arranged.

In other words, the webs overlap the edge of the straps 15 around the bridge height. The distance between two adjacent bars 13 corresponds to the height of the strap 15 , ie the transverse dimension of the strap 15 , The width of the bars 13 that determines itself between the straps 15 resulting joint width. Incidentally, the present invention is not based on insulating material 11 limited to web heights of 4 mm. Rather, it is any other web height suitable, provided that the web height is smaller than the support width of the straps 15 , The contact width of the straps 15 denotes the thickness of the straps 13 or the distance between the front 12 the insulating material body 11 and the surface passing through the straps 15 is formed. Alternatively, the straps 15 joint-free or with a minimum joint spacing of at most 5 mm on the insulating base body 11 arranged. The joint-free or largely joint-free arrangement of the straps 15 offers the advantage that both material for the otherwise required grouting and the operation of grouting can be saved.

The straps 15 are preferably cohesively, for example by bonding by means of an adhesive mortar on the front 12 the insulating material body 11 arranged. Particular preference is given to a Renowall ^® mortar according to DIN EN 12004 for use. Alternatively, any other adhesive is suitable that a cohesive connection of the straps 15 with the front 12 the insulating material body 11 guaranteed. The insulating material body 11 has a bulk density that is at least 14 kg / m ³ or more. The contact width of the straps is between 18 mm and 50 mm. In this context, it should be noted that the drawing is not to scale, so that the aforementioned support width of the straps in the 1 and 2 is not reproduced to scale.

Particularly preferred is the gross density of the insulating body 11 furthermore less than or equal to 25 kg / m ³ . According to a further preferred embodiment of the invention, the contact width of the straps between 18 mm and 25 mm. Optionally below the thermal insulation composite system is a base rail 21 arranged. The base rail 21 For example, includes two interconnected L-shaped metal or plastic rails. The connection of the two L-profile-shaped metal or plastic rails is designed so that one of the L-rails has a right-angled contact edge 22 and the other thigh 23 a support for the insulating base body 11 forms. The other of the L-rails is in this case on the leg 23 arranged that one of the thighs 24 parallel to the contact edge 22 is aligned and so the edge of the investment 22 , the thigh 23 and the thigh 24 form a U-shaped profile. The edge of the investment 22 as well as the thigh 24 are provided with a plurality of holes and / or slots by means of which the base rail 21 on the wall 10 or the wall section 10 or with the insulating bodies 11 connectable trained and set up. Alternatively, instead of the base rail 21 be used at least substantially impermeable and / or water-repellent insulation board. Preferably, it is in the as the base rail 21 used insulation board around a perimeter insulation board or an XPS insulation board.

2 shows a plan view and a cross-sectional view of a possible embodiment of the insulating base body 11 , In plan view, the webs described above 13 shown parallel to one another with one of the height of the straps 15 are arranged corresponding distance from each other and thus between the webs 13 lying receiving areas 14 for the straps 15 form.

In particular, the cross-sectional view is a profiled edge region 16 to take in accordance with a further advantageous embodiment of the invention. The profiled edge area 16 serves the positive lateral connection of several of the insulating base body 11 , In the 2 shown profile form represents only one possible execution of the profiled edge region 16 In principle, any profile shape is suitable, provided that the profiled edge regions 16 are formed and arranged so corresponding to each other that the insulation body 11 can be positively connected with each other. The profiled edge area 16 is alternatively designed and set up as a stepped rebate or as a tongue and groove profile. Of course, the thickness of the insulating body is 11 is not limited to this value, but is arbitrary depending on the desired thermal insulation effect or belonging to the corresponding thermal conductivity group and thus includes usually thicknesses between 10 mm to over 400 mm. For example, have insulation base body 11 the thermal conductivity group 035 has a thickness of 60 mm.

The insulating material body 11 preferably consists entirely of expanded polystyrene (EPS). However, it is also possible that the insulating body 11 only partly consists of polystyrene and to a further part of other thermoplastics. Alternatively, there is the insulating body 11 partially or completely made of extruded polystyrene (XPS), polyurethane, expanded Neopor ^®, Bakelite ^® or mineral insulating materials, for example, to plates solidified mineral wool.

Particularly preferred are the straps 15 a length between 15 cm and 100 cm. The height of the straps is more preferably between 3.5 cm and 30 cm. In other words, preferably large-sized straps come 15 with an area between 15 cm × 3.5 cm up to an area of 100 cm × 30 cm for use. Particularly preferred are the straps 15 for a 25 mm overlay width, the following surface formats (length × height): 22.8 cm × 4 cm, 22.8 cm × 5.4 cm or 22 cm × 6.5 cm. More preferably, the straps are impregnated with a hydrophobing agent. Preferably, the hydrophobizing agent is one-sided on the straps 15 applied, namely on the side of the straps 15 after application to the insulating base body 11 directed to the outside and exposed to the weather. Alternatively, this is the insulating body 11 facing side of the straps 15 impregnated, or the straps 15 are completely impregnated with the hydrophobing agent.

Advantageously, the straps 15 set up and designed such that the water absorption of the straps 15 at least 0.4% and up to 30%. The water absorption of the straps 15 is determined essentially by the total porosity and the pore radius maximum. For aprons with a water absorption of about 20%, the pore radius maximum is for example about 3.6 μm on average, the porosity about 35%, the bulk density about 1.75 g / cm ³ and the pore volume about 200 mm ³ / G. The abovementioned parameters merely serve to illustrate the dependence of the water absorption on the abovementioned physical parameters of the aprons 15 , Therefore, the present invention is not limited to the aforementioned parameters, but rather any type of strap with a combination of parameters is suitable, which requires a water absorption in the range between 0.4% and 30%.

Preferably, the straps 15 designed as brick or Klinkerriemchen. Thus, the external appearance of a clad with the inventive thermal insulation composite wall corresponds to that of an ordinary verklinkerten or brick-faced building wall. For this purpose, the straps 15 preferably cut from solid bricks or clinker to the desired support width. According to a particularly preferred embodiment of the invention, the straps 15 formed ceramic, for example as extruded ceramic straps. Particular preference is given as a ceramic strapping Kolumba ^® , straps manufacturer Petersen and Tegl. for use. According to another preferred embodiment, the pore volume, in particular that of the Kolumba straps, is greater than or equal to 20 mm ³ / g. More preferably, the pore radius maximum on average greater than 0.2 microns. The aforementioned straps 15 are preferably cut from a solid brick or made as a shaped aprons in a corresponding shape without cutting. More preferably have the straps, particularly the Kolumba ^®, -Riemchen 15 , the following surface formats (length × height), namely at a support width of 2.5 cm or 3 cm, the area format 52.8 cm × 3.7 cm, with a support width of 2 cm, the area format 52.8 cm × 10, 8 or with a support width of 2.5 cm a length of 52.8 cm and a height in a range of 2 cm to 6.5 cm. However, the present invention is not limited exclusively to the aforementioned area formats. According to the present invention, any area format having a length in the range of 15 cm to 100 cm and a height in the range of 3.5 cm and 30 cm is basically suitable.

It is preferred between the straps 15 and the front 12 of the insulating material body 11 a - not shown in the figures - arranged armor. The reinforcement preferably comprises a reinforcing fabric and a reinforcing adhesive by means of which the reinforcement on the front 12 of the insulating material body 11 is applied. When using the aforementioned reinforcement are the straps 15 preferably cohesively, for example by gluing, arranged on the reinforcement. Further preferred is the insulating base body 11 formed web free, so that the front 12 as far as possible flat and the reinforcement is arranged flat on this.

3 shows a cross-sectional view of the on a wall 10 or a wall section 10 arranged inventive thermal insulation composite device. On the wall 10 is optional a leveling compound layer 17 applied. The insulation basic body 11 are cohesively on the surface of the wall 10 or on the leveling plaster layer 17 arranged. The connection of the insulating material body 11 with the wall 10 or the leveling layer 17 is preferably formed as an adhesive connection by means of a suitable connecting means. The bonding agent used is, for example, a cement-containing mortar or other adhesives, for example from the group of dispersion adhesives.

Further preferred is the insulating base body 11 by means of fasteners 19 exclusively or additionally with the wall 10 or the wall section 10 connected so that the insulating body 11 non-positively on the wall 10 or the wall section 10 is arranged. The fasteners 19 are preferably designed as dowel screws, knock anchors or thermal bridge screw anchors.

On the front of the insulating base body 11 are in the of the jetties 13 limited recording area 14 the straps 15 arranged. The straps 15 are preferably cohesively on the insulating body 11 arranged. Preferably, the material is closed by an adhesive bond, for example by a suitable adhesive mortar. The in the area of the bridges 13 existing joints 20 are filled with a grout.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202007017751 U1 [0004]

Cited non-patent literature

• DIN EN 12004 [0025]

Claims (12)

Thermal insulation composite device for insulating a wall ( 10 ) comprising at least one insulating base body ( 11 ), whereas on the front ( 12 ) of the insulating base body ( 11 ) parallel to each other and spaced apart webs ( 13 ) forming at least one receiving area ( 14 ) for the guided reception of a plurality of straps ( 15 ) are arranged and the straps ( 15 ) in the reception area ( 14 ) at least substantially cohesively on the front side ( 12 ) of the insulating base body ( 11 ) between the bridges ( 15 ) are arranged, characterized in that the insulating body ( 11 ) has a bulk density greater than or equal to 14 kg / m ³ and the straps ( 15 ) have a contact width between 18 and 50 mm. Thermal insulation composite device according to claim 1, characterized in that the insulating base body ( 11 ) a profiled edge area ( 16 ) for the positive lateral connection of several of the insulating body ( 11 ) with each other. Thermal insulation composite device according to one of claims 1 or 2, characterized in that the insulating base body ( 11 ) consists at least substantially of expanded polystyrene. Thermal insulation composite device according to one of the preceding claims, characterized in that the straps ( 15 ) have a length between 15 cm and 100 cm and a height between 3.5 cm and 30 cm. Thermal insulation composite device according to one of the preceding claims, characterized in that the straps ( 15 ) are impregnated with a hydrophobing agent. Thermal insulation composite device according to one of the preceding claims, characterized in that the straps ( 15 ) are arranged and designed such that the water absorption of the straps ( 15 ) Is 0.4% to 30%. Thermal insulation composite device according to one of the preceding claims, characterized in that the straps ( 15 ) are designed as bricks, clinker, - concrete or extrusion straps. Thermal insulation composite device according to one of claims 1 to 6, characterized in that the straps ( 15 ) are ceramic. Thermal insulation composite device according to one of claims 1 to 8, characterized in that between the straps ( 15 ) and the front ( 12 ) of the insulating base body ( 11 ) A reinforcement is arranged. Arrangement for insulating a wall ( 10 ) or a wall section ( 10 ) comprising a plurality of thermal insulation composite devices according to one of claims 1 to 9, wherein the thermal insulation composite devices on the wall ( 10 ) or the wall section ( 10 ) are arranged. Arrangement according to claim 10, characterized in that the insulating base body ( 11 ) at least substantially cohesively with the wall ( 10 ) or the wall section ( 10 ) are connected. Arrangement according to one of claims 10 or 11, characterized in that the insulating base body ( 11 ) by means of fastening means ( 19 ) frictionally against the wall ( 10 ) or the wall section ( 10 ) is arranged.

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