RU2734410C2 - Collapsible heat-insulating combined system and method of its manufacturing and removal - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to a heat-insulating combined system (1) and a method for production thereof. Heat-insulating combined system (1) has at least one layer of heat-insulating material (2), at least one layer of plaster-soil (3), applied on layer of heat-insulating material (2), at least one reinforcing layer (4), introduced into layer of plaster-soil (3) or applied on it, and at least one coating for final finishing (5), closing outside heat-insulating combined system (1). Reinforcing layer (4) has at least one protruding section (6) for removal of reinforcing layer (4) together with covering layers of plaster (3, 5) from layer of heat-insulating material (2), fixed on base, by force transfer to protruding section (6).

EFFECT: invention ensures the thermal insulation combined system disintegration due to the reinforcing layer removal simplification, as well as its reuse.

12 cl, 3 dwg

Description

The invention relates to a heat-insulating combined system comprising at least one layer of heat-insulating material, at least one layer of plaster-ground applied to a layer of heat-insulating material, at least one reinforcing layer introduced into the layer of plaster-ground or applied on it, and at least one finishing coating covering the outside of the thermal insulation combination system. In particular, the invention relates to a dismountable and / or recyclable thermal insulation combination system, as well as to its manufacture.

In addition, the invention relates to a method for manufacturing a thermal insulation combination system, in particular a collapsible and / or recyclable thermal insulation combination system, preferably on the walls of buildings, wherein a layer of thermal insulation material is placed on the base, in particular on the wall of a building, then on This layer of heat-insulating material is applied with a layer of plaster-ground, and then a reinforcing layer is introduced into the layer of plaster-ground or applied to it, after which a finishing coat is applied to the outside to finish the heat-insulating combined system. The term "building wall" can refer in the context of the invention, in particular to the surface of the floor, roof and / or wall of a building.

In addition, the invention also relates to a method for removing the thermal insulation combined system from the wall of a building on which it was installed.

The problem of energy saving has arisen not only in connection with the new energy policy. In order to be able to heat the building most efficiently in recent years, a lot of money has been invested in building thermal insulation. So, for example, by placing heat-insulating combined systems on the outer sides of the walls of buildings, they achieved a reduction in heat loss through infiltration. As a rule, traditional thermal insulation combined systems were used for this, with the help of which, although it was possible to achieve adequate thermal insulation, they had significant drawbacks, which until now were hardly noticeable. In particular, until now, little attention has been paid to the fact that many of the thermal insulation combination systems used so far, after their dismantling, for example after the end of their intended use phase, are special waste that cannot be reused. Recycling of the materials used to form these traditional thermal insulation combined systems in the circulation of recyclable materials is usually unprofitable or simply impossible. Firstly, the materials used themselves often cannot be reused, and, secondly, the materials are often combined with each other in such a way that it is impossible to achieve their separation into separate materials suitable for reuse. For this reason, the disposal of dismantled conventional thermal insulation combined systems can be expensive. In addition, the formation of these traditional thermal insulation combination systems prevents the sparing and environmentally friendly management of the available resources. In addition, this waste management of dismantled conventional thermal insulation combined systems is contrary to the German regulations of the Waste Disposal, Recycling and Prevention Act and the Waste List Ordinance.

Yet these disadvantages of traditional thermal insulation combined systems are now recognized in industry and politics. Report of the Institute of Building Physics. Fraunhofer (IBP-Bericht BBHB 019/2014/281), drawn up on behalf of the industry association for thermal insulation combined systems, sets the task of initiating research work with the aim of developing environmental, economic and technical measures for the material and energy recycling of components of thermal insulation combined systems after their dismantling to separate them.

Therefore, the object of the invention is to provide a collapsible and / or separable thermal insulation combined system.

For a heat-insulating combined system of the type mentioned, this problem is solved using the features of claim 1. In particular, according to the invention, in order to solve the problem, it is proposed that the reinforcing layer, in the already laid (i.e., inserted) state, have at least one protruding section and / or application point, so that by means of the transfer of force to the protruding section and / or the application site, including the plaster layer / layers surrounding / surrounding the reinforcing layer, in particular the plaster-primer layer and / or the topcoat, it was possible to separate the reinforcing layer from the layer of thermal insulation material reinforced on the base.

In particular, according to the invention, it can be provided that the base is a building wall, in particular a brick wall or a concrete wall, or an existing thermal insulation combined system, or at least a layer of insulating material thereof on brickwork or concrete. With the inventive arrangement of the thermal insulation combination system, the layers of the thermal insulation combination system which are put together can be separated almost without residue from each other, so that they can be recycled again into the material cycle. By transferring the force to the projecting area and / or the place of application, in particular by using a tool, the reinforcing layer, together with the plaster-primer layer and all other layers applied to the plaster-primer layer, can be separated from the layer of thermal insulation material, in particular by take off. In this case, provision can be made for the loose plaster to be collected for reuse.

In order to allow a particularly simple separation of the layer of thermal insulating material from the substrate, it may be advantageous if the layer of thermal insulating material is not adhered to the substrate under assembly conditions or is not capable of adhesion. It is particularly advantageous here if a layer of heat-insulating material is applied or can be applied to the substrate under assembly conditions, in particular exclusively by means of mainly removable and / or non-heat-conducting connecting elements in the form of pins. Suitable connecting elements can be, for example, screws, nails and / or rivets. Advantageously, the connecting elements are recessed so that the outwardly projecting side of each connecting element is flush with the surface of the layer of thermal insulation material.

A particularly advantageous embodiment of the claimed thermal insulation combination system can provide that the reinforcing layer consists of a fabric, in particular a tear-resistant fabric. This can be particularly advantageous if the reinforcing layer is a fiberglass fabric. To achieve the best transfer of force and uniform separation of the reinforcing layer from the layer of thermal insulation material, it can be advantageous if the reinforcing layer is made at least in part from a web of fabric or several webs of fabric.

The separation takes place according to the invention mainly along the base on which the thermal insulation combined system is located, the action of force or the transfer of force occurs mainly at an angle of at least 10 or 20, or 30, or 40, or 50 degrees, or more relative to the surface of the base, in particular, essentially at right angles.

To simplify the removal of the reinforcing layer, it may be expedient if at least one dimensional parameter of the reinforcing layer in at least one direction is greater than the corresponding dimensional parameter in this direction of at least one or all other layers of the thermal insulation combined system ... In particular, it can be advantageous if at least one portion of the reinforcing layer protrudes relative to at least one other layer of the thermal insulation combined system under assembly conditions. Alternatively or additionally, it may be advantageous if at least the protruding section and / or the place of application of the reinforcing layer during the assembly of the heat-insulating combined system is not introduced into or applied to the plaster-ground layer. Thus, it is possible to more easily grip at least the projecting section and / or the application point, in particular with the aid of a tool for transferring a force, in particular a tensile force, to the reinforcement layer. In this case, it can be especially advantageous if the projecting section and / or the place of application of the reinforcing layer is or is at the end of the reinforcing layer in the form of a web of fabric.

A particularly robust and nevertheless very easy to dismantle form of the claimed thermal insulation combined system can provide that the plaster-primer layer has a total thickness of 3 mm to 10 mm, in particular 5 mm to 8 mm.

The claimed thermal insulation combination system can have, in comparison with already known thermal insulation combination systems, such an advantage that all components of the thermal insulation combination system, placed on the base under assembly conditions, are collapsible and / or recyclable. In this case, it can be advantageous in particular if the layer of heat-insulating material is made at least in part from mineral wool.

The next solution to the above initial problem is to combine the features of the claimed method according to claim 5 of the claims. In particular, according to the invention, in order to solve this problem, it is proposed to attach a layer of heat-insulating material not by gluing to the base, and / or, preferably exclusively, by means of removable and / or non-heat-conducting connecting elements in the form of pins. In this case, according to the invention, it can in particular be a building wall as a base. Suitable connecting elements can be, for example, screws, nails and / or rivets. Mostly the connecting elements are recessed. Due to the fact that the claimed method provides that the application of a layer of heat-insulating material to the base is not an integral connection of materials, the layer of heat-insulating material can be completely and completely removed from the base if it is necessary to dismantle the heat-insulating combined system made using the inventive method. This is advantageous in that there is no need for costly removal of the adhered layer of heat-insulating material, and the individual components of the heat-insulating combined system manufactured using the inventive method can be more easily separated from each other.

Another, in particular, independent proposal for solving the above problem according to the invention can provide that the reinforcing layer under assembly conditions takes place and / or in at least one region has an elevation relative to at least one layer, in particular , a layer of thermal insulation material and / or a layer of plaster-ground or all layers of a thermal insulation combined system. In this case, it can be advantageous if the application site is a projecting section. Due to the presence of the application site and / or the protruding portion, it is possible to transfer a force, in particular a tensile force, to the reinforcing layer. This can be done, for example, with a tool and / or simply by hand.

In a particularly advantageous embodiment of the method according to the invention, it can also be provided that for the application of the plaster-primer layer, only one part of it is first applied, then a reinforcing layer is applied to this part, and only then the rest of the plaster-primer layer is applied to the reinforcing layer. , as a result of which the reinforcing layer is located between two parts of the plaster-primer layer.

In order to achieve the best fixation, in particular, of the claimed heat-insulating combined system based on the base, it may be advisable if the base initially has drilled holes, into each of which a dowel is inserted, and the layer of heat-insulating material is fixed on the base using screws screwed into the dowel. In order to avoid cold bridges, it can be especially advantageous if the screws used are not capable of conducting heat, for example through a coating or a non-heat conductive material, such as plastic. In particular, the screws can be drowned in.

In order that the protruding section and / or the place of application does not spoil / spoil the general appearance of the surface lined with the thermal insulation system, and / or to avoid possible undesirable effect of force on the protruding section and / or the place of application, it can be advantageous if the reinforcing layer is applied to base in such a way that its end protrudes / protrudes from the side of the roof and / or the end from the side of the base of the building. In particular, it can be advantageous in this case if the projecting section is covered with a roof edge and / or a plinth trim. As a result, it is possible to achieve that in the assembled thermal insulation combined system produced by the inventive method, the protruding section and / or the place of application is hidden and therefore, in particular, not visible to the eye. Thus, it is possible to prevent an act of vandalism in case of illegal dismantling of the declared thermal insulation combined system.

If, using the claimed method, it is necessary to insulate a building wall or a part of it, in which there is a window, then it may be advisable if the protruding section of the reinforcing layer is located in the base area where there is a window, under the window sill and / or on or in the roller shutter box. In particular, it may be advisable if the protruding portion of the reinforcing layer is covered by them.

For the possibility of making a durable and at the same time easily dismantled thermal insulation combined system, it can be advantageous if the total thickness of the plaster-primer layer is from 3 mm to 10 mm, in particular from 5 mm to 8 mm.

In a particularly advantageous embodiment of the method according to the invention, provision can be made for the layer of heat-insulating material to be made, at least in part, of mineral wool.

In a particularly advantageous embodiment of the method according to the invention, only such components are used for the production of the thermal insulation combined system which are suitable for recycling.

The reinforcing layer of the thermal insulation combined system is of decisive importance for the quality of the entire insulation system. As a rule, it is responsible for the in-plane stress distribution in the plaster so that, for example, cracks in the plaster-primer layer and / or in the finishing coat can be avoided. These cracks can appear, for example, as a result of the fact that the individual layers of the plaster of the thermal insulation combined system harden at different rates, as a result of which tensile stresses arise with a corresponding threat of cracking. In the claimed method of manufacturing, in particular, the claimed heat-insulating combined system, the reinforcing layer performs another task. In addition to the already mentioned purpose, it serves to remove the plaster layers applied to the layer of thermal insulation material almost without leaving any residues if it is necessary to dismantle the thermal insulation combined system produced in this way. Therefore, in a particularly advantageous embodiment of the method according to the invention, provision can be made for the reinforcing layer to be made of a fabric, in particular a tear-resistant fabric. Advantageously, the reinforcing layer is made, at least in part, from fabric webs. The most suitable fabric may be, for example, fiberglass fabric.

In addition, the invention also relates to a method for removing from the base installed on it a thermal insulation combined system, in particular, the claimed thermal insulation combined system, as described and claimed herein, and / or a thermal insulation combined system manufactured by the claimed method, as described and claimed here. ... According to the invention, it is provided here that by applying a force, in particular a tensile force, to the protruding section and / or the place of application of the reinforcing layer, predominantly all plaster layers covering the reinforcing layer are removed from the layer of thermal insulation material of the thermal insulation combined system located below them. This is advantageous in the sense that the individual components of the thermal insulation combination system thus removed can be more easily separated from one another and thus recycled materials can be recycled.

In an advantageous embodiment of the method according to the invention, it may be advantageous if by means of the method the layer of heat-insulating material applied to the substrate can, in particular, be completely separated from the plaster-primer layer and / or the adhesive layer applied to this layer of heat-insulating material.

Alternatively or additionally, it may be advantageous if the layer of thermal insulation material is removed from the substrate by removing one or more of the connecting elements, in particular removed without leaving a residue. The connecting elements can be, for example, screws, nails and / or rivets.

The invention is described in more detail based on an exemplary embodiment, but is not limited to this exemplary embodiment. Other embodiments according to the invention result from the combination of individual or several features of the claims with each other and / or with individual or more features of the exemplary embodiments.

FIG. 1 is a schematic representation of the claimed thermal insulation combined system under assembly conditions;

FIG. 2 shows an exemplary embodiment from FIG. 1 shown as an assembly drawing;

FIG. 3 shows an example of embodiment from FIGS. 1 and 2, whereby the plaster layers are separated from the layer of heat-insulating material by the action of force on the reinforcing layer.

FIG. 1 - 3 show a special form of execution of the heat-insulating combined system, indicated in general by the position 1.

FIG. 1 declared thermal insulation combined system 1 is placed on the base. The basis here is the wall of building 8, which is a brickwork.

The claimed heat-insulating combined system 1 has a layer of heat-insulating material 2, which is attached or can be fixed to the wall of the building 8 by screwing. To do this, drilled holes are initially made in the building wall, into each of which a dowel 11 is inserted or can be inserted. With the help of non-conductive screws 10, the layer of heat-insulating material 2 is fixed or can be fixed on the wall of the building 8 by screwing the screws 10 into the dowels 11 through the layer of heat-insulating material. On the layer of heat-insulating material 2, only one part 12 of the plaster-primer layer 3 is applied. On this one part 12 of the plaster-primer layer 3, a reinforcing layer is placed 4. Thanks to the layer of the second part 13 of the plaster-primer 3, applied to the reinforcing layer 14, the reinforcing layer is located , thus, inside the plaster-primer layer 3. On the plaster-primer layer 3, a finishing coating 5 is applied, which serves to close the thermal insulation combined system 1 from the outside. Such a topcoat 5 can be, for example, a suitable finishing plaster.

The reinforcing layer 4 of the claimed thermal insulation combined system 1 has at least one protruding section 6. The protruding section 6, in the exemplary embodiment according to FIG. 1 to 3, the place of application 7. By transferring the force to the protruding portion 6, it is possible, as shown in FIG. 3, separate the reinforcing layer 4 together with the layers of plaster 3, 5 surrounding it from the layer of heat-insulating material 2, fixed on the wall of the building 8.

As can be seen in FIG. 1, the layer of heat-insulating material 2 is fixed or can be fixed on the wall of the building under assembly conditions only with the help of connecting elements 9 in the form of screws 10. Unlike the previously known heat-insulating combined systems, the claimed heat-insulating combined system 1 does not have a continuous connection of the material, as, for example, when gluing. Removable connecting elements 9 can, if necessary, be easily removed, after which the fixation disappears.

The reinforcing fabric 4 is, in the exemplary embodiment according to FIG. 1 - 3 tear-resistant fabric. A suitable fabric for this can be, for example, a fiberglass fabric. In this case, the fabric can be a continuous canvas, so that it can be removed, in particular, along the total length of the building wall 8.

To capture the application site 7 in the form of a protruding section 6, in particular with the help of a tool, the length of the reinforcing layer 4, which is a fabric sheet, must be greater than all other layers 2, 3, 5 of the thermal insulation combined system 1 and / or the building wall 8. Therefore, in the assembled state, the place of application 7 of the reinforcing layer 4 is not located inside the layer of plaster-primer 3.

The total thickness of 16 layers of plaster-primer 3 is from 5 mm to 8 mm.

All components of the thermal insulation combined system 1, placed on the wall of the building 8, can be dismantled and / or reused.

The layer of insulating material 2 is made at least in part of mineral wool. In addition, it may be advantageous if the layer of heat-insulating material 2 is made up of several adjacent layers of insulating material.

FIG. 3 shows how, by the action of a force on the reinforcing layer 4 at the place of application 7, the reinforcing layer 4, together with all layers of plaster 3, 5 enclosing it, is removed or can be removed from the layer of heat-insulating material 2 fixed on the wall of the building 8. In particular, it is possible to achieve removal almost without the remainder of all layers of plaster from the layer of thermal insulation material 2, so that the individual components of the claimed thermal insulation combined system 1 are more easily separated from each other and thus returned to recycling.

As shown in FIG. 1 to 3, it can be advantageous if the protruding portion 6 is at the end, in particular at the longitudinal end of the reinforcing layer 4. In addition, it can be provided that the reinforcing layer 4 has two or more two places of application 7. As can be seen in FIG. ... 1 - 3, the reinforcement layer 4 has an attachment 7 located at the end of the roof side 17 and at the end of the base of the building 18. The attachment sites 7, made in the form of protruding sections 6, are hidden or can be hidden under the edge of the roof and under the trim basement. In addition, it can be provided that in the window area they are or could be under the window sill and / or on or in the roller shutter box and be covered or could be covered by them.

After removing the reinforcing layer 4 from the layer of heat-insulating material 2, the heat-insulating combined system 1 can be completely dismantled by removing the connecting elements 8 and removing the layer of heat-insulating material 2 from the wall of the building 8. In addition, thanks to the declared device of the heat-insulating combined system 1, it is possible to separate from each other almost without residue other individual components of the thermal insulation combined system 1, so that when the declared thermal insulation combined system 1 is removed, there is no or almost no special waste.

List of designations

thermal insulation combined system

1 layer of thermal insulation material

2 layer of plaster-primer

3 reinforcing layer

4 finishing coat, top coat

5 protruding section of the reinforcing layer

6 place application

7 building wall

8 connecting piece

9 screw

10 dowel

11 one part of a layer of plaster-primer

12 second part of the plaster-primer layer

13 size of the reinforcing layer

14 the size of other layers

15 total thickness of the plaster-primer layer

16 roof end

17 end from the side of the base of the building

Claims (12)

1. Thermal insulation combined system (1), including at least one layer of thermal insulation material (2), at least one layer of plaster-primer (3) applied to the layer of thermal insulation material (2), at least one a reinforcing layer (4) inserted into a layer of plaster-ground (3) or placed on a layer of plaster-ground (3), and at least one finishing coating (5) covering the outside of the thermal insulation combined system (1), characterized in that the reinforcing layer (4) has at least one protruding section (6) for the possibility of removing the reinforcing layer (4) together with the surrounding plaster layers (3, 5) from the layer of heat-insulating material (2), fixed on base, by applying force to the protruding section (6). 2. Heat-insulating combined system (1) according to claim 1, characterized in that the layer of heat-insulating material (2) is not glued to the base during installation and is placed or is placed on the base using mainly removable and / or non-conductive connecting elements (9) in the form of pins, in particular by means of screws (10), nails and / or rivets, preferably, wherein said connecting elements (9) are recessed, and / or that the reinforcing layer (4) is formed from fabric, in particular made of fiberglass fabric, preferably in such a way that the reinforcing layer (4) is at least partially composed of at least one fabric web. 3. Thermal insulation combined system (1) according to claim 1, characterized in that at least one dimensional parameter (14) of the reinforcing layer (4) is greater in at least one direction than the corresponding dimensional parameter (15) , at least one or all other layers (2, 3, 5) of the heat-insulating combined system (1), in particular, so that at least one section (6) of the reinforcing layer (4) under installation conditions protrudes relative to of at least one of the other layers (2, 3, 5) of the heat-insulating combined system (1), and / or that at least the protruding section (6) of the reinforcing layer (4) is not introduced into the layer under installation conditions plaster-primer (3) or not placed on it. 4. Thermal insulation combined system (1) according to one of paragraphs. 1-3, characterized in that the total thickness (16) of the layer of plaster-primer (3) is from 3 mm to 10 mm, in particular from 5 mm to 8 mm, and / or that all components under the conditions of installation of the thermal insulation combined system ( 1), mounted on the base, are collapsible and / or recyclable, in particular that the layer of heat-insulating material (2) is made at least partially of mineral wool. 5. A method of manufacturing a heat-insulating combined system (1), in particular a reusable heat-insulating combined system (1), wherein a layer of heat-insulating material (2) is placed on the base, in particular on the wall of a building, and a layer of heat-insulating material (2) a layer of plaster-primer (3) is applied, a reinforcing layer (4) is introduced and / or placed into or onto a layer of plaster-primer (3), and finally a coating for finishing (5) is applied outside, characterized in that a layer of heat-insulating material ( 2) are not attached to the base by gluing and are attached to the base using removable and / or heat-incapable connecting elements (9) in the form of pins, in particular using screws (10), nails and / or rivets, preferably, with the indicated the connecting elements (9) are located with a recess or that the reinforcing layer (4) has a protruding section (6) during installation and / or is attached with a protrusion in at least one area and with respect to at least one, in particular, a layer of heat-insulating material (2) and / or a layer of plaster-ground (3) or all layers (2, 3, 5) of a heat-insulating combined system (1), in particular so that due to the protruding section (6), it is possible to transfer a force, in particular a tensile force, to the reinforcing layer (4). 6. The method according to claim 5, characterized in that the reinforcing layer (4) has a protruding section (6) during installation and / or is attached with a protrusion in at least one region relative to at least one, in particular , a layer of heat-insulating material (2) and / or a layer of plaster-soil (3) or all layers (2, 3, 5) of the heat-insulating combined system (1), in particular so that due to the protruding section (6), force transfer is possible, in particular the tensile force on the reinforcing layer (4). 7. The method according to claim 5, characterized in that for the application of a layer of plaster-soil (3), its first part of the layer (12) is first applied, then a reinforcing layer (4) is placed on said first part (12), and then on the reinforcing layer (4), its second part of layer (13) is applied, as a result of which the reinforcing layer (4) is introduced between two parts (12, 13) of the plaster-soil layer (3), and / or that the base is first provided with drilled holes, in each of which they are inserted along the dowel (11), and the layer of heat-insulating material (2) is attached to the base using screws (10), which are not able to conduct heat, screwed into the dowels (11), and / or screws (10) located with a drowning. 8. The method according to claim 5, characterized in that the reinforcing layer (4) is placed on the base in such a way that its end from the side of the roof (17) and / or its end from the side of the base of the building (18) protrudes / protrude, in particular , such that the projecting section (6) is covered by the edge of the roof and / or the plinth trim, and / or that any or said projecting section (6) of the reinforcing layer (4) is located in the region of the base, in which there is a window, under the window sill and / or on or in the roller shutter box, in particular, covered by them. 9. A method according to claim 5, characterized in that the total thickness (16) of the plaster-ground layer (3) is from 3 mm to 10 mm, in particular from 5 mm to 8 mm, and / or that the layer of heat-insulating material (2 ) is made at least partly of mineral wool. 10. The method according to one of paragraphs. 5-9, characterized in that all components of the thermal insulation combined system (1) are recyclable and / or that the reinforcing layer (4) is made of fabric, in particular of fiberglass fabric, preferably in such a way that the reinforcing layer (4) consists at least in part from fabric webs. 11. A method of removing from the base of the thermal insulation combined system (1), mounted on this basis, in particular, according to one of paragraphs. 1-4 and / or made by the method according to one of claims. 5-10, characterized in that by applying a force, in particular a tensile force, to the protruding section (6) of the reinforcing layer (4), the reinforcing layer (4) and all layers of plaster (3, 5) covering it are removed from the underlying layer thermal insulation material (2) thermal insulation combined system (1). 12. The method according to claim 11, characterized in that by means of said method, the layer of heat-insulating material (2) placed on the base is detachable, in particular completely from the layer of plaster (3) and / or adhesive layer applied to this layer of heat-insulating material, and / or that any or said layer of thermal insulation material (2) is removed from the substrate, in particular without residue, by removing one or more connecting elements (9), in particular screws (10), nails and / or rivets, wherein, predominantly, these connecting elements (9) are recessed.

Images