EP1743114A1 - Insulation of a conduit in escape and/or rescue routes and partitioning of a building wall - Google Patents

Abstract

The invention relates to an insulation of a conduit in escape and/or rescue routes with an insulating material layer, which is made of flammable material and which surrounds the conduit. The invention also relates to a partitioning of a building wall in an essentially vertical or horizontal orientation with at least one through opening, which forms a soffit and through which at least one conduit is led that passes through the building wall. The conduit is surrounded by an insulating material layer made of flammable material. In order to meet high fire protection requirements while also being structurally simple and thus being able to be produced economically, it is provided, with regard to the partitioning, that the conduit (1), together with the insulating material layer (2), is covered by a conduit shell (4) made of non-flammable material having insulating properties. The conduit shell (4) is joined to opposite surfaces (16) of the building wall (14, 18) in a flush manner.

Description

 Insulation of a pipeline in escape and / or rescue routes and partitioning of a building wall

The invention relates to insulation of a pipeline in escape and / or rescue routes with an insulation layer of combustible material surrounding the pipeline. In addition, the invention relates to a partitioning of a building wall in a substantially vertical or horizontal orientation with at least one passage opening forming a soffit for the passage of at least one pipeline penetrating the building wall, the pipeline being surrounded by an insulation layer made of combustible material.

Insulation of a pipeline in escape and / or rescue routes is known from the prior art. For the insulation of such pipes, insulation materials with a high water vapor diffusion resistance number are used, which are also used for the thermal insulation of refrigeration pipes. These insulating materials consist of combustible materials and are usually designed as pipe shells which are placed on the pipe, the pipe shells having an incision running in the axial direction in order to be placed on the pipe. The joint that forms in the axial direction of the pipe shell, like the transverse joints between adjacent pipe shells, is glued with adhesive systems in order to achieve a low water vapor permeability in these areas as well. Adhesive tapes are usually used for this purpose, which are glued to the outer surface in the area of the corresponding joints. If such refrigeration lines or other pipelines are arranged in the area of escape and / or rescue routes, then the pipelines or refrigeration lines must be laid in fire-resistant installation shafts or installation ducts or above a fire protection-tested ceiling construction. This procedure is very complex both technically and in terms of cost. In addition, there is the problem that corresponding pipelines and / or cooling lines must also be led through wall and ceiling constructions. In order to To achieve a fire resistance duration, the pipelines and / or refrigeration lines with an insulation layer made of combustible material with foaming agents (intumescent material) must be inserted into corresponding openings in the walls of the building. These foaming agents are usually placed in the form of a bandage or cuff around the insulation layer made of flammable material.

From EP 1 236 942 A1, for example, a partitioning of a building wall in a substantially vertical or horizontal orientation is known, which building wall has at least one through opening forming a soffit for the passage of at least one line penetrating the wall for energy and / or Has information manager. The line is covered at least in the area of the through opening with a sleeve designed as a tubular shell made of mineral fibers, which essentially connects directly to the reveal of the through opening designed as a bore and closes the through opening completely radially and axially in a heat-resistant and smoke-tight manner. Such partitioning has proven itself in the prior art, but can only be used to a limited extent in existing insulation of pipelines in escape and / or rescue routes if this insulation has an insulating material layer of combustible material surrounding the pipeline.

Furthermore, DE 37 35 136 A1 discloses a heat-insulating pipe duct, in particular for fire walls or fire blankets. This pipeline bushing consists of foam surrounding the pipeline, which is interrupted by an internal fire stop. A lost sheet metal formwork is arranged on the local foam, which is surrounded by another external fire stop made of an elastic material. Mineral wool or a mineral wool pack, for example, can be provided as the external fire stop. In the same way, the inner fire stop consists of a mineral wool pack.

Furthermore, WO 00/52278 A1 is at least a partition of a building wall in a substantially vertical or horizontal orientation with at least one passage opening forming a reveal for the passage a pipeline penetrating the building wall is known. The pipeline is covered with a pipe shell, which pipe shell is held in a mineral wool plate cut out accordingly.

Based on this prior art, the invention is based on the development of an insulation according to the invention in such a way that it fulfills the high requirements of fire protection and at the same time is structurally simple and therefore inexpensive to manufacture. Furthermore, the invention is based on the object of designing a generic partitioning accordingly.

The solution to this problem provides for an insulation according to the invention that the pipeline with the insulation layer is covered with a pipe shell made of non-combustible material having insulation properties.

In the insulation according to the invention of a pipeline in escape and / or rescue routes, it is therefore provided that, in addition to the insulation layer made of combustible material, a pipe shell is placed on the pipeline from the outside. Such a pipe shell can be made relatively light and consist of mineral fibers. The pipe shell completely surrounds the pipe. The fire protection encapsulation of the fire load, which originates from the combustible insulation layer, takes place through the pipe shell made of non-combustible material with insulating properties. This is sufficient for pipelines with media that have a higher temperature than the ambient temperature.

According to a further feature of the invention, it is provided that the pipe shell encases the entire insulation layer and rests with an inner surface on the outer surface of the insulation layer. It is also provided that the pipe shell is designed to be compressible and / or elastically deformable in its axial and / or radial direction, so that the pipe shell lies both over the entire surface of the insulation layer and also in the axial direction, for example during installation Wall has sufficient flexibility to create a sealing seal between the wall and the pipe shell.

As already explained above, it has proven to be advantageous to form the tubular shell from synthetic resin-bound mineral fibers, in particular from rock wool and / or glass wool, the synthetic resin-bound mineral fibers preferably having a melting point of at least 600 ° C., in particular 900 ° C. and preferably more than 1,000 ° C. exhibit. Alternatively, the pipe shell can be made of calcium silicate, vermiculite, foam glass and / or plasterboard. In both cases, it is advantageous to design the pipe shell with a bulk density between 20 and 600 kg / m ³ , in particular between 20 and 200 kg / m ³ .

According to a further feature of the invention, it is provided that the pipe shell is formed in one piece and has an opening running in the axial direction, which is slit-shaped. Alternatively, the pipe shell, in particular in the case of pipes with a larger diameter, can also be formed in two or more parts, the individual elements being connected to one another with clamp-shaped elements or with adhesive strips and being fastened to the pipe. The opening in the pipe shell running in the axial direction has an activatable adhesive, for example a hot-melt adhesive, in the area of at least one surface, with which the opening can be closed by gluing opposite surfaces. In the same way, end faces of the pipe shell can also be formed with an activatable adhesive in order to connect pipe shells which are arranged adjacent to one another in the axial direction of the pipe.

It is further provided according to a further feature of the invention that the pipe shell has a lamination on its outer surface, which consists in particular of a film made of plastic or metal, in particular light metal, such as aluminum, and preferably has a material thickness of less than 1 mm. When using insulation in refrigeration lines where the media temperatures are between 0 ° C and ambient temperature, it has proven to be advantageous to arrange a capillary-active fabric between the pipe shell and the insulation layer, which at least partially covers the inner surface of the pipe shell and the outer surface of the insulation layer covers and is guided through an opening, in particular in the axial direction, of the pipe shell to the outer surface of the pipe shell. The capillary-active tissue can be placed on the insulation layer in a first step and then surrounded with the pipe shell and pressed against the insulation layer. An evaporation surface for occurring water is formed over the section of the capillary-active tissue that leads outwards, so that it can be easily removed from the insulation.

The capillary-active fabric preferably covers at least 5% of the inner surface area of the pipe shell or the outer surface area of the insulation layer. However, it may also be necessary to cover the entire outer surface area of the insulation layer or the entire inner surface area of the pipe shell in order to allow sufficient drainage of water that occurs within the insulation.

To solve the problem, with regard to the partitioning according to the invention according to a first embodiment, it is provided that the pipeline with the insulation layer is covered with a pipe shell made of non-combustible material having insulation properties, the pipe shell being flush with opposite surfaces of the building walls.

An alternative solution to the problem provides for a partitioning according to the invention that the pipeline with the insulation layer is covered with a pipe shell made of non-combustible material with insulation properties, the pipe shell penetrating the building wall in the area of the passage opening and firing against the reveal - and sealed smoke-tight. In both configurations, an advantageous installation of pipelines insulated with combustible insulating materials is achieved, which can be carried out by fire-resistant wall or ceiling constructions. The fire protection partition is achieved through the pipe shell, in particular from mineral fibers.

According to a further development, in the first embodiment of the partitioning according to the invention, it is preferably provided that the pipe shell is connected to an end face of the building wall, in particular is glued, in order to achieve a tight seal that prevents a fire transfer to the combustible insulation layer in this area. In this case, fire and heat resistant adhesives are used which, in accordance with the material of the pipe shell, are resistant up to the temperatures mentioned above.

Further developments of the partitioning according to the invention result from the relevant subclaims and from the following description of the associated drawing, in which preferred embodiments of an insulation and a partitioning are shown. In the drawings: FIG. 1 shows a first embodiment of an insulation of a pipeline in a partially sectioned side view;

Figure 2 shows a second embodiment of insulation of a pipeline in a sectional side view;

3 shows the insulation according to FIG. 2 in a cross section along the section line III-III in FIG. 2;

FIG. 4 shows a first embodiment of a partition in the area of a building floor in a sectional side view;

FIG. 5 shows a first embodiment of a partition in the area of a building wall in a sectional side view; Figure 6 shows a second embodiment of a partition in the area of a floor in a sectional side view and

Figure 7 shows a second embodiment of a partition in the area of a wall opening in a sectional side view.

In Figure 1, a pipe 1 is shown in an escape and / or rescue route. The pipe 1 is covered with an insulation layer 2 made of combustible material. The pipeline 1 can consist of non-flammable or flammable pipe materials. The insulation layer 2 completely encases the pipeline 1 and lies against the outer circumferential surface 3 of the pipeline 1.

The insulation layer 2 is surrounded by a pipe shell 4, which consists of a non-combustible, insulating material, namely synthetic resin-bound mineral fibers made of rock wool. The resin-bonded mineral fibers from rock wool have a melting point of more than 1,000 ° C. The pipe shell 4 has a bulk density of more than 90 kg / m ³ and is sufficiently pressure-resistant.

On the outer surface 5 of the pipe shell 4, a lamination 6 made of aluminum foil is glued, which completely covers the outer surface of the pipe shell 4. The pipe shell 4 is formed in one piece and has a slit-shaped opening 7, shown in FIG. 3, which extends in the axial direction and which allows the pipe shell 5 to be elastically deformed such that it can be placed over the insulation layer 2.

In the area of the opening 7, two radially extending surfaces 8 are arranged, which have a thin layer of an adhesive 9.

FIG. 2 shows a second and alternative embodiment of the insulation of the pipeline 1. In addition to the construction elements already described with reference to FIG. 1, the embodiment according to FIG. 2 has a capillary-active one Fabric 10 is provided, which is arranged between the pipe shell 4 and the insulation layer 2. The capillary-active tissue 10 is in full contact with the outer surface 11 of the insulation layer 2 and the inner surface of the pipe shell 4.

A free end 12 of the capillary-active tissue 10 is guided through the opening 7 to the outside, the capillary-active tissue 10 being arranged on a partial area of the outer surface 5 of the tube shell 4 and connected to the tube shell 4.

Via the capillary-active fabric 10, it is possible to remove water formed in the insulation from the insulation, for example to prevent damage to the insulation layer 2 or the pipeline 1 or the pipe shell 4 by moistening.

In FIG. 4, a partition 13 is shown in the area of a building floor 14, in which the tubular shell 4 with end faces 15 is flush with the surfaces 16 of the building floor 14. An adhesive 17 is arranged between the end faces 15 and the surfaces 16, which has not only adhesive but also sealing properties.

FIG. 5 shows a partition 13 according to FIG. 4 in the area of a building wall 18, the structural configuration of which corresponds to the structural configuration of the partition 13 according to FIG. 4.

FIGS. 6 and 7 show second embodiments of partitions 13 comparable to the embodiments according to FIGS. 4 and 5, in which, in contrast to the embodiments according to FIGS. 4 and 5, the insulation is not in the area of the surfaces 16 of the building floor 14 or the building wall 18, but through the opening 20 in the building floor 14 or the building wall 18. In this regard, an adhesive can be provided on the outer surface of the lamination 6, with which the insulation is fixed in the opening 20. Concrete or mortar can also be used for the closure be used. As an adhesive, expanding materials can also be provided here, for example, in the event of fire, which lead to improved sealing of the partition 13 in the event of a fire.

Claims

Expectations

1.Insulation of a flammable or non-flammable pipeline in escape and / or rescue routes with an insulation layer made of flammable material surrounding the pipeline, characterized in that the pipe (1) with the insulation layer (2) with a pipe shell (4) made of non-flammable , Material with insulating properties is encased.

2. Insulation according to claim 1, characterized in that the pipe shell (4) surrounds the entire insulation layer (2) and rests with an inner surface on an outer surface of the insulation layer (2).

3. Insulation according to claim 1, characterized in that the pipe shell (4) is designed to be compressible and / or elastically deformable in its axial and / or radial direction.

4. Insulation according to claim 1, characterized in that the pipe shell (4) consists of synthetic resin-bonded mineral fibers, in particular rock wool and / or glass wool and preferably has a melting point of at least 600 ° C, in particular 900 ° C and preferably more than 1,000 ° C ,

5. Insulation according to claim 1, characterized in that the pipe shell (4) consists of calcium silicate, vermiculite, foam glass and / or plasterboard.

6. Insulation according to claim 1, characterized in that the pipe shell (4) has a bulk density between 20 and 600 kg / m ³ , in particular between 20 and 200 kg / m ³ .

7. Insulation according to claim 1, characterized in that the pipe shell (4) is formed in one piece and has an opening (7) extending in the axial direction, which is slot-shaped.

8. Insulation according to claim 7, characterized in that the opening (7) in the area of at least one surface (8) has an activatable adhesive (9) with which the opening (7) can be closed by gluing opposite surfaces (8).

9. Insulation according to claim 1, characterized in that the pipe shell (4) on its outer surface (5) has a lamination (6), which consists in particular of a film made of plastic or metal, in particular light metal, such as aluminum, and preferably a material thickness less than 1 mm.

10. Insulation according to claim 1, characterized in that a capillary-active fabric (10) is arranged between the pipe shell (4) and the insulation layer (2), which at least partially the inner surface of the pipe shell (4) and the outer surface of the insulation layer (2) covers and is guided through an opening (7), in particular in the axial direction, in the pipe shell (4) to the outer surface (5) of the pipe shell (4).

11. Insulation according to claim 10, characterized in that the capillary active fabric (10) covers at least 5% of the inner surface area of the pipe shell (4) or the outer surface area of the insulation layer (2).

12. partitioning of a building wall in a substantially vertical or horizontal orientation with at least one passage opening forming a soffit for the passage of at least one pipeline penetrating the building wall, the pipeline being surrounded by an insulation layer made of combustible material, characterized in that the pipeline (1) the insulation layer (2) is encased in a pipe shell (4) made of non-combustible material with insulation properties, the pipe shell (4) being flush with opposite surfaces (16) of the building wall (14, 18).

13. partitioning according to claim 12, characterized in that the pipe shell (4) with an end face (15) with the building wall (14, 18) is connected, in particular glued.

14. partitioning of a building wall in a substantially vertical or horizontal orientation with at least one passage opening forming a soffit for the passage of at least one pipeline penetrating the building wall, the pipeline being surrounded by an insulation layer made of combustible material, characterized in that the pipeline (1) is coated with the insulation layer (2) with a pipe shell (4) made of non-combustible material with insulation properties, the pipe shell (4) covering the building wall (14, 18) in the area of the Passing through opening (20) and sealed against the reveal fire and smoke-tight.

15. partitioning according to claim 12 or 14, characterized in that the pipe shell (4) encased the entire insulation layer (2) and rests with an inner surface on an outer surface of the insulation layer (2).

16. partitioning according to claim 12 or 14, characterized in that the pipe shell (4) is designed to be compressible and / or elastically deformable in its axial and / or radial direction.

17. partitioning according to claim 12 or 14, characterized in that the pipe shell (4) consists of synthetic resin-bonded mineral fibers, in particular rock wool and / or glass wool and preferably a melting point of at least 600 ° C, in particular 900 ° C and preferably more than 1,000 ° C.

18. partitioning according to claim 12 or 14, characterized in that the pipe shell (4) consists of calcium silicate, vermiculite, foam glass and / or plasterboard.

19. partitioning according to claim 12 or 14, characterized in that the pipe shell (4) has a bulk density between 20 and 600 kg / m ³ , in particular between 20 and 200 kg / m ³ .

20. partitioning according to claim 12 or 14, characterized in that the tubular shell (4) is formed in one piece and has an opening (7) which extends in the axial direction and is formed in the shape of a slot.

21. partitioning according to claim 20, characterized in that the opening (7) in the region of at least one surface (8) has an activatable adhesive (9) with which the opening (7) can be closed by gluing opposite surfaces (9).

22. partitioning according to claim 12 or 14, characterized in that the pipe shell (4) on its outer surface (5) has a lamination (6), which consists in particular of a film made of plastic or metal, in particular light metal, such as aluminum, and preferably has a material thickness of less than 1 mm.

23. partitioning according to claim 12 or 14, characterized in that between the pipe shell (4) and the insulation layer (2) a capillary active fabric (10) is arranged, which the inner surface of the pipe shell (4) and the outer surface of the insulation layer (2) at least partially covers and is guided through an opening (7), in particular in the axial direction, in the pipe shell (4) to the outer surface of the pipe shell (4).

24. Partitioning according to claim 23, characterized in that the capillary-active fabric (10) covers at least 5% of the inner surface area of the pipe shell (4) or the outer surface area of the insulation layer (2).