NL1011532C2 - Compartmentalization of mineral wool insulation. - Google Patents

Description

COMPARTMENTATION OF INSULATION OF MINERAL WOOL

The present invention relates to a thermally insulated wall, comprising a layer of air-containing insulating material adjoining the wall and an air-sealing sealing layer applied to the outside of the layer of insulating material.

Such a thermally insulated wall is generally known, for instance in the form of blankets or plates of mineral wool, which are provided on the outside with a layer of foil or paper.

Such insulating materials are, of course, often used for insulating buildings, but also for insulating walls, which are included in production installations, in particular process installations. High temperature gradients often occur here, where the insulating material must prove its favorable properties.

In general, such insulation is satisfactory. Hereby it is assumed that the insulating material, for instance the mineral wool, is resistant to the temperatures which the thermally insulated wall can assume, for instance when a high temperature prevails on the other side. The temperature resistance of mineral wool is therefore generally high.

In forming the mineral wool into processable units in the form of blankets, trays or plates, an adhesive material is generally used which is formed by a resin. Such resins or any other binders also have a high temperature resistance. When the temperature rise gradients with such a thermally insulated wall are not too high, such a construction can withstand high temperatures.

However, there are situations where high temperature gradients rise over time, for example, 1011532 Λ 2 * when the insulated wall is formed by a wall of a tube through which a fluid is transported at a very high temperature, for example steam. There is then the danger that this temperature rise gradient leads to an exothermic reaction of the adhesive. This phenomenon is known under the name of "punking".

This exothermic reaction leads to a high temperature, so that there is a risk of this reaction propagating further through the insulation and leading to the formation of smoke and destruction of the insulation and surroundings. This could even lead to a fire.

The object of the present invention is to avoid the above mentioned problem.

This object is achieved in that the layer of insulating material is divided into compartments by air-sealing partitions extending substantially transversely of the insulated surface.

Owing to the fact that it is already known to close off the insulation material from the outside world by a layer extending between the insulation material and the environment, the supply of oxygen is already hindered to some extent. Nevertheless, it is quite possible that, due to the generally large volumes in which the insulating material is present, the exothermic reaction, which requires oxygen, withdraws it from the said volume.

The available volume of oxygen is reduced by the compartmentalisation, so that the exothermic reaction can hardly propagate. This greatly reduces the danger of "punking".

A similar configuration is known from GB-A-380 240, albeit with powdered insulating material that contains little or no air, so that this configuration does not solve the problem posed.

According to a first preferred embodiment, at least one separating surface, which extends substantially parallel to the insulated wall, is arranged in the layer of insulating material. This leads to a further 1 fi i 1 5's -

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V * 3 compartmentalization, reducing available volume.

According to yet another preferred embodiment, the wall is flat and the partition walls in a cross-section parallel to the wall have a structure of a closed-cell network. This also leads to an improvement of the above-mentioned effect and in particular in the configuration of a flat wall.

However, when the wall comprises at least the outer wall 10 of a substantially cylindrical body and the layer of insulating material extends around the outer wall of the body, and at least at the location of the jacket of the cylindrical body, the layer of insulating material is at least in the axial direction of the body compartmentalized by radially extending interfaces, a configuration is also obtained which is suitable when using tubes or, for example, cylindrical boilers.

Preferably, the interfaces are made of a material that is resistant to at least the same temperature as the wall is resistant to.

The interfaces are therefore made of foil, for example metal foil.

According to an attractive preferred embodiment, the radial interfaces are provided with bent lips to fix the radial interfaces to one of the insulating layers.

Other attractive preferred embodiments are evident from the other sub-claims.

The present invention will now be elucidated with reference to the annexed drawings, in which: figure 1 shows a partly broken away perspective view of a first embodiment of the invention; figure 2: a perspective view of a second embodiment of the invention, and 1011532 * 4 figure 3: a partly broken away perspective view of a third embodiment of the invention.

In figure 1 a tube 1 is shown, which is suitable for transporting a fluid having a different temperature from the environment.

A first layer of insulating material, such as mineral wool, is applied around the pipe.

A thin layer of foil 3 has been applied around this layer 1. The layer 2 of insulating material and the foil layer 3 each only extend over a limited area of the length of the pipe 1. Fixing takes place by means of for instance an adhesive, for which of course a temperature-resistant adhesive must be used, such as resin, in particular a phenolic resin. However, it is also possible to use mechanical adhesives, such as a layer of gauze, of metal wire or metal tape applied around the foil layer 3.

A second layer of mineral wool 4 and a second foil layer 5 are provided around the first layer of mineral wool and the associated foil layer. These are attached in the same way as the respective first layer.

In the same manner, a third layer of mineral wool and a third foil layer 7 are also applied. Each of these layers has only a limited extension in the axial direction of the pipe 1. In the axial direction, these layers are separated by partitions 8, which are provided in their interior with an opening 9 with which they are arranged around the pipe 1.

Of course, a cut 10 can be made in the partition walls 8 to position the partition wall around the tube when one end of the tube is not accessible. After the partition wall 10 has been fitted, lips 11 arranged on the periphery of the partition wall can be bent to the insulating layers 7 already present. However, it is also possible, as shown in figure 1, only half the number of: --·· . ... - <K 1 *): * /: i S -v 3 -ii 5 bend the lips and, after applying the insulation applied on the other side of the dividing wall 8, bend the other lips, so that the situation is obtained, as shown in figure 1.

It will be clear that various variants can be used; it is thus possible, for example, as can be seen in figure 2, to use the partition walls 12, which only extend over the radial dimension of a single layer. This in itself involves more labor during application, but leads to a somewhat firmer structure. Incidentally, another drawback is that, depending on the number of layers, partitions 12,13,14 of different sizes must be used. However, an advantage of this embodiment is that the staggered partition walls provided lead to better adhesion of the insulating material; the adhesives of the first two layers could be omitted.

Although these embodiments relate to round pipes, they are also applicable to pipes with a different cross section, such as oval or rectangular.

As already mentioned in the preamble, the present invention can also be applied to other-shaped elements, such as bodies, boilers or flat walls. Figure 3 shows an example of a flat wall 15 on which two layers of insulating material have been applied, namely a first layer 16, a foil layer 17 applied thereon, a second layer 18 and a sealing foil layer 19.

The first layer of insulating material 16 is separated in compartments 20a, 20b, etc. by partitions 21. Furthermore, there are other partitions 22 extending perpendicularly to the partition wall 21, which also contribute to the compartmentalization.

f Likewise, the above-applied layer 18V is compartmentalized.

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It will be clear that other forms of compartmentation are possible, such as in a honeycomb structure, and so on. It is of course also possible to use more than two layers, for example three layers. Furthermore, the invention is not limited to a multi-layered structure, it is equally applicable to a single-layered insulating structure.

1 v 1; 7.

Claims (14)

1. Thermally insulated wall, comprising a layer of air-containing insulating material adjoining the wall and an air-sealing sealing layer arranged on the outside of the layer of insulating material, characterized in that the layer of insulating material is divided into compartments by substantially transverse to the 10 insulated flat-extending air-sealing separating surfaces. 2. Thermally insulated wall according to claim 1, characterized in that in the layer of insulating material at least one separating surface extending substantially parallel to the insulated wall is arranged. A thermally insulated wall according to claim 1 or 2, characterized in that the wall is flat, and that dividing surfaces in a section parallel to the wall have the structure of a closed-cell network. 4. Thermally insulated wall according to claim 1 or 2, characterized in that the wall comprises at least the outer wall of a substantially cylindrical body, that the layer of insulating material extends around the outer wall of the body, and that at least at the location of the jacket of the cylindrical body, the layer of insulating material is compartmentalized at least in the axial direction of the body by radially extending interfaces. A thermally insulated wall according to claim 30, characterized in that the layer of insulating material is compartmentalized in the tangential direction by the radial interfaces interconnecting interfaces. 6. Thermally insulated wall according to claim 4 or 5, characterized in that the body is provided with at least two layers of insulating material which are separated from each other by partitions extending in the axial and tangential direction of the body. 1011532 * ψ Thermally insulated wall according to any one of claims 4-6, characterized in that the body is formed by a conduit suitable for transporting fluids with a temperature different from the ambient temperature. 8. Thermally insulated wall according to one of the preceding claims, characterized in that the interfaces are made of a material which is resistant to at least the same temperature as the wall is resistant to. Thermally insulated wall according to one of the preceding claims, characterized in that the interfaces are made of foil, for example metal foil. A thermally insulated wall according to any one of claims 4-7, characterized in that the radial interfaces are provided with bent lips for fixing the radial interfaces to one of the insulating layers. 11. Thermally insulated wall according to claim 10, characterized in that at least a part of the number of bent lips is arranged on the circumference of the radial interface for attachment to the circumference of the outer insulating layer. 12. Thermally insulated wall according to claim 6 or 7, characterized in that the radial interfaces of each of the layers are mutually displaced in an axial direction. 13. Insulating material for manufacturing an insulated body according to any of the preceding claims, comprising mineral wool blankets provided with adhesives on one of their surfaces and having a substantially rectangular surface, of a length equal to or slightly larger the circumference of the body to be insulated is then the other dimension equal to the length of the compartments in the axial direction. Radial dividing wall for the production of an insulated body according to any one of the preceding claims, which wall is made of a metal foil, has a substantially annular configuration, and at its circumference of folding lips is provided. 5 t 0 1 15 3 2