DE3711869A1 - Insulating arrangement for construction elements - Google Patents

Abstract

The invention relates to an insulating arrangement for construction elements such as walls. The construction element is provided, in sections, with an insulation which insulates against sound and over which a protective casing is arranged.

Description

The invention relates to an insulating arrangement for construct tion elements.

The invention includes both sound and heat and / or cold insulation.

Under the term "construction elements" all Components understood that sound, heat or cold need insulation. This includes flat components as well as pipelines or the like. For example Pipelines for the transport of a cooling gas or a Coolant must both thermally and against Sound emissions are isolated because both the thermal Losses during the transport route through the pipeline, as well as minimizing outside noise  should be. The latter aspect is for example when conveying granular materials in the front reason.

This creates a variety of practical problems.

With pure sound insulation, which is usually always automatically coupled with thermal insulation with as little construction effort as possible complete noise cancellation can be achieved. Just with kilometer-long pipelines or large walls (for example of kettles) there are considerable quantities of insulation material necessary. Your arrangement and assembly often causes difficulties.

With cold insulation, problems arise from that setting a certain temperature profile between inside and outside to shift the Dew point in the area of insulation.

Corresponding pipe insulation arrangements are known in which there is initially a closed cell around the tube full-surface cold insulation layer is placed on the then again sound insulation, for example in the form of a Coat made of mineral wool.

This continues between the inner insulating layer and the outer insulating jacket as well as around the insulating coat around a vapor barrier, for example in the form of closed aluminum sheets.

However, practical experience has shown that such Vapor barriers are not absolutely safe. Rather it will  again and again the formation of condensation between the two vapor barriers and thus within the mineral wool Insulation observes what is undesirable.

In the case of pipelines, it is known from DE-OS 34 02 233 all around the pipeline an insulation material and in Distance to this one outer protective sheath. Here, tubing should be arranged vertically or inclined parts with collecting elements for on the inside of the protective jacket arising or draining condensate water provided by the inside of the protection coat to the outside and the collected Discharge condensed water to the outside.

Such an arrangement does not remedy the above Problems with the insulation of cooling pipes because of the Dew point is usually inside, and therefore there condensation forms, which is released via the "geöff neten "protective coat can not run off. In addition are often increased requirements for sound insulation posed when this is met by the known arrangement can be.

The invention has for its object an insulation to offer arrangement for construction elements that possible As simple as possible, material-saving and easy to assemble is. The insulation arrangement should preferably also for cold insulation of construction elements, preferably be suitable for the insulation of cooling pipes and above all, the best possible sound iso offer, avoiding the state of the art Disadvantages known in the art, in particular a condensation water formation within the sound insulation. About that In addition, the insulating arrangement is said to be advantageous Embodiment if possible also security requirements, especially from a fire protection point of view.  

In a first embodiment, the invention proposes an insulation arrangement for construction elements before, at the one between the construction element and an im Distance to the protective jacket arranged insulation jacket made of a dimensionally stable, sound-absorbing material exists and the space between the construction element and Protective jacket only partially filled, so that different Sections remain free.

Surprisingly, it has been shown that - in deviation from the proposals of the prior art - it is not necessary to completely fill the space between the structural element and protective jacket with an insulating material that it is sufficient to arrange the insulation only in sections.

The insulating jacket can be in the form of web-shaped, spaced apart, parallel to the construct tion element and protective jacket extending elements be educated.

For example, with tubular insulation then, the isolation in the form of individual, over the length of the tube spaced from each other Make rings from a suitable insulating material. It then remains between the individual rings a ring-shaped free space.

It is also possible to shape the construction element an "insulating ring" helical to form a then also helical free space between the individual sections of the helical insulation include.  

While in the aforementioned embodiments, the isolation tion essentially parallel to the construction element or the protective jacket runs, the Invention in an alternative embodiment, the Isolation essentially perpendicular between construction element and protective jacket, that is, to train them in the form of individual "spacers". To the Example of an insulation arrangement for a pipeline individual webs of insulating material would then be radial between the pipeline and the latter at a distance protective coat, the sections between the individual insulating bars are designed as open spaces are.

Tests have shown that the one with a sound absorbing Insulated material filled space only a maximum of 30 % of the total space must be without a characteristic Deterioration in sound insulation.

The insulation arrangement described above serves in particular soundproofing.

Especially if, in addition to sound insulation, too thermal insulation is to be achieved the invention a further embodiment in which the insulating jacket described above a first part the overall insulation forms, the second part of one the continuous insulating layer adjacent to the insulating jacket is formed. The full-surface insulation layer, the preferred as the construction element is adjacent, ensures the desired thermal insulation during the above arranged (interrupted) insulating jacket essentially  serves the sound insulation and be on the previously written way, that is, it is enough here only a partial filling of the room with the sound insulating insulating material.

The invention suggests for design and assembly reasons in an advantageous embodiment, between Iso lierschicht and insulating jacket to arrange a separating element. This provides a way to support the individual given insulation.

In a further alternative embodiment of the inven It is proposed to use the separating element as a vapor barrier to train. This embodiment is particularly in Isolation arrangements are proposed in which a cold insulation should take place.

The prior art provides for such insulation beaten to arrange the vapor barrier outside. It is also have already been suggested using an internal insulation surrounded by and at a distance from a vapor barrier to arrange a second, external vapor barrier, the respective gaps completely with different Insulation materials are filled.

However, it has been shown that a complete seal can not always be achieved. For example Isolation arrangements for pipelines must be finite cuts are connected to each other and to each other, the outer protective jacket also frequently has weld seams or the like that keeps leaking of the system.  

A simple homogeneous system has certain values of the state variables v (volume), p (pressure) and T (temperature) in every equilibrium state, which must be constant in the entire system. However, its state is already determined by specifying two of these state variables, so that the third is a function of the other two for each state of equilibrium.

Due to the zeroth law of thermodynamics is the thermal equation of state of the phase:

f (p, T, v) = 0

Now consider the one described above Isolation arrangement, so it can easily be seen that between the inner and outer vapor barrier in the practical application, there is always a temperature gradient that is or the temperature difference to Example depending on the ambient atmosphere ver can change. The change in temperature and thus a state variable is then necessarily due to the aforementioned thermodynamic relationship at constant tem volume (space between inner and outer vapor barrier) a change in pressure. This is also an (uncontrolled bare) change in thermodynamic equilibrium given. Leakage occurs when the pressure changes points to an (uncontrollable) air (atmosphere) Exchange and especially a shift of the dew point in the area of the outer insulating jacket and thus too a dampening of the soundproofing, which is naturally unimportant wishes.  

The invention is based on the knowledge that a practically do not set quasi-adiabatic system leaves. The invention is based on the further finding that that - as already described at the beginning - the sound insulation is hardly noticeably impaired if the corresponding Insulation material not all over - as in the prior art nik - but only in sections.

Such an arrangement can then - like another one provides advantageous embodiment of the invention be designed so that a gas and / or liquid passes (exchange) preferably in all three rooms directions is given.

In this way, with an insulation arrangement with a go through the interior associated with the construction element the insulating layer and a vapor arranged above it lock between this and one of them at a distance The protective sheath formed a room that was only partially filled with a sound-insulating material is, the invention in turn different execution forms suggests the arrangement of the insulating jacket so make that a largely free gas and / or Moisture exchange is guaranteed.

This can be the case, for example, with one described above Arrangement with annular insulating webs done by that these are formed with appropriate through holes are. Likewise, the insulating can also be in the contact area sections to the outer protective jacket or internal vapor barrier recesses can be formed for example, with pipe insulation, an air and  Allow moisture to pass in the axial direction.

In the case of the first two variants described embodiment with an education of Sound insulation in the form of "vertical / radial" distance pieces results in the desired flowability of self.

Another embodiment of the invention proposes between insulating jacket (or its sections) and internal vapor barrier or external protection jacket allow one or more air to pass through to provide spacers.

These are preferably between the insulating jacket and steam lock arranged, as it is here in particular for condensation water formation occurs, which is easier to drain away can.

For example, with pipe insulation, the distance holder made of corrugated iron around the vapor barrier like body, which then, for example, with a Perforated sheet covered or designed as a perforated sheet itself is to the desired air or moisture to ensure passage.

The insulation, for example made of mineral wool, is then put on outside.

For example, in an embodiment with radial ver running sections of the insulating jacket can called the th spacer according to a further embodiment  the invention in the form of spacers, which are reduced in cross-section in their longitudinal extent are formed, so the flow through the room between the vapor barrier and protective jacket increase.

To a specific flowability or one targeted atmosphere exchange between the partially with the insulating jacket and the surrounding area to enable another advantageous suggests embodiment of the invention, in the outer protective jacket at least two air- and moisture-permeable through openings see.

As a rule, a variety of such passages openings arranged on the outer protective jacket, wherein these of very small diameter (for example <1 mm) can be designed.

Tests have shown that the area of the passage openings in relation to the total area of the protective jacket can be less than 1%, preferably less than 0.5%. Even then there will be sufficient air and moisture guaranteed exchange.

Although due to the described embodiment practically a "forced ventilation" sets, so the invention proposes in an expanded Embodiment additionally before, a forced ventilation over a corresponding supply and exhaust air opening and if necessary to provide suction and / or blowing units arranged therein.  

It becomes an additional security of a permanent Ventilation is provided.

The openings in the outer protective jacket are so small that the sound exit through them is practically negligible is cash. If necessary, the openings can be added still be soundproofed, for example by the arrangement of an in front of the respective opening spaced fender or arrangement a sound-absorbing, but air and moisture permeable material on the inside of the opening. This function can be used for sound insulation take over yourself.

A further improvement in soundproofing can help can be achieved, for example, in that the insulating layer and / or the insulating jacket with respect to those supporting them Components (pipeline, vapor barrier, outer protective jacket) through an interposed deadening layer iso be lated. The deadening can be known Way with an anti-drone cardboard, a rubber or Plastic insert made.

With pure thermal insulation, both the inner Insulating layer as well as the outer insulating jacket from one open-cell insulation material such as rock wool or a polyvinyl chloride or polyurethane soft be made of foam.

The invention suggests as a material for cold insulation a closed cell for the inner insulation layer Insulating material such as a polyurethane or polystyrene hard foam or a foamed glass (so-called foam glass) in front.  

Both the vapor barrier and the outer insulating jacket are preferably made of an aluminum or steel sheet produced. The spacers mentioned can also be used (Spacers) made of aluminum or steel.

Realize with an insulation arrangement according to the invention advantages are obvious. Both with a pure Sound insulation, as well as with a combined heat / Soundproofing allows the invention to be minimal Losses in sound insulation with much less insulation lation material. In addition, the invented appropriate arrangement of the sound insulation particularly fold, if for example in the form of strips or Spacers are made.

In addition, one with a thermal iso lation combined sound insulation due to the Invention according to the intended cavities between the individual Be range (sections) of the sound-insulating material a (forced) ventilation consciously enabled by a appropriate perforation of the outer protective jacket on can be optimized.

The invention has thus recognized that it in particular with cold insulation, with which at the same time a sound insulation should be connected, it does not matter as the state of the art provides, one if possible tightly pack the soundproofing material or this behind an external vapor barrier to arrange. Rather, the invention is based on one conscious air and moisture permeability of the outside Protective jacket to adjust, while interrupted Sound insulation jacket.  

In this way it becomes (unwanted) moisture penetration of the material of the sound insulation reliably prevented. The invention enables an almost constant Temperature profile over the area of sound insulation (For example, in the embodiment mentioned one Pipe cold insulation between the vapor barrier and the outer protective jacket). At the same time, however Temperature differences or external temperature influence a pressure change in the room mentioned readily possible.

Any moisture (condensation) can be easily due to the preferably in three room directions with passage areas designed space the sound insulation can be safely removed.

Isolation arrangements of the type described are common in companies in the chemical or petrochemical sector used. Practice has shown that in particular here, unfortunately, there are always fires that move quickly along pipe insulation. In particular with vertically arranged construction elements (Tubes) could be used for the described design Formation of a so-called chimney effect are coming means that the fire moves very quickly in the open spaces from bottom to top. The invention also offers here Remedy in an advantageous embodiment. Is to provided that the one or more boundaries Surfaces at least in sections with one under heat provide an insulating layer-forming fire protection coating are. For this purpose, it is particularly useful to have the freedom assigned surface of the separating element (the vapor barrier) at least in sections with such fire protection coating.  

Such an insulating layer-forming fire protection coating according to DIN 4102 are characterized in that they are under increased heat (e.g. in the case of a fire) foam, the foam being largely non-flammable. The foam then acts as a fire protection wall Progress of the fire at least over a certain Period prevented.

According to an advantageous embodiment of the invention the coating should be applied in such an amount that the corresponding free space after foaming the material is filled in as completely as possible and thus forming an almost hermetic seal in the the fire cannot pass.

In an embodiment in which between the insulating jacket, Construction element, separating element, protective jacket and / or Insulating layer one or more, an air passage ensuring spacers is (are), is it to achieve the most complete seal possible advantageous, both surfaces delimiting the free space and if necessary additionally the Ab arranged in it stand at least partially with such insulation layer-forming fire protection coating. There is then sufficient loading even with larger free spaces Layering material available to make a complete To fill the room after foaming.

Trials have shown that it is not necessary, however is the surfaces or the spacer over the entire Length (area) to coat, it is rather sufficient that To coat parts at certain intervals in order to to enable sections of the spaces to be filled,  where the fire is stopped. This will also Material and thus costs saved without security significantly affect.

Insulating fire protection coatings of the named Art are known to the person skilled in the art and are, for example sold under the trademark unitherm by Permatex ten. These are substances based on orga African nitrogen compounds, carbohydrates, ammonium salt and / or polyvalent aluminum carbon.

In the sense of the invention can of course substances with the same effect are also used.

Tests have shown that such fire protection measures above all, the inner insulating layer is protected becomes. Because the fire in the appropriate places can no longer pass, it comes towards the fire away to a temperature gradient even in the insulating layer, which at least at a distance behind that through the foam filled space remains intact and its function can continue to meet. Especially when promoting Chemicals through a pipe is the mainstay The greatest possible reliability of the insulation Importance.

The invention proposes a further advantageous Embodiment before, alternatively or in addition to insulation layer forming fire protection coating solid fire protective elements in the insulating jacket and / or the insulating layer, preferably perpendicular to the construction element (of the pipeline). The fire protection elements can be disk-shaped, especially  so-called Palusol fire protection panels are proposed. These form a solid wall for a fire. At correspond Appropriate temperature loads also foam these sheets and seal the space around the construction element white ter from, so that a further oxygen supply under will break.

These measures ensure a high level of fire protection poses. Instead of the Palusol fire protection boards mentioned can of course also use other fire protection panels Find use.

The insulation arrangement described is simple, inexpensive producible and easy to assemble. Depending on whether one pure sound, heat or cold insulation, given if in combination with fire protection, aimed for be, the insulation arrangement on one of the proposed genes.

The invention is based on an embodiment example explained in more detail, but in no way limited the idea of the invention.

In the single figure is an isolation arrangement for one Longitudinal section of pipeline through which cold air flows shown, using four different types of insulation structure are specified.  

The reference number 10 shows a pipeline, here with a square cross section.

At a constant distance around the pipe 10 , in which cooling air is transported here, a square tube 12 made of an aluminum sheet, which serves as a vapor barrier.

The space between the pipeline 10 and the vapor barrier 12 is filled with a closed-cell insulating material 14 , here a rigid polyurethane foam. The insulating material (the insulating layer) 14 ensures a secure and constant arrangement of the square tube 12 at a distance from the pipeline 10 . If necessary, however, suitable spacers can also be provided, which are then preferably arranged in a sound-absorbing manner.

An outer protective jacket 16 is arranged around the square tube 12 at a constant distance. This has a plurality of small through openings 18 on its surface, which are described in more detail below. The openings 18 have a diameter of less than 1 mm.

A sound-absorbing insulating jacket is arranged between the square tube 12 and the outer protective jacket 16 . In the drawing, the four outer surfaces of the square tube 12 each assigned four different arrangements of the sound-insulating material 20 are shown.

Between the upper surface 12 a of the square tube 12 and the corresponding upper surface 16 a of the protective jacket 16 , the insulating material 20 extends from wall to wall, but its surface is formed with bead-shaped depressions 22 which are perpendicular to the plane, so that tubular channels between the insulating material 20 and the associated walls 12 a , 16 a are formed. Furthermore, connection openings (not shown) which pass through the insulating jacket 20 from one side to the opposite side are provided.

The right section of the sound insulation, i.e. the area between the side wall 12 d of the square tube 12 and the side wall 16 d of the protective jacket 16 is - similarly as described above - filled with a sound-insulating insulating jacket 20 , which, however, with sections, vertical and horizontal channels 24 is formed. In the drawing, a vertical channel sections 24 is shown a, the horizontal three Ka nalabschnitten 24 is traversed b, creating a combination of the vapor barrier 12 to the sheath 16, the openings 18 are arranged in the protective sheath 16 is preferably in the range of the channel portions 24 b are.

The lower section of the soundproofing is divided into three different zones. The lower wall 12 c of the square tube 12 is adjacent to a corrugated strip 26 made of aluminum, which is arranged so that the corresponding cavities run parallel to the direction of flow of the cooling gas. A perforated plate 28 made of aluminum rests on the corrugated strip 26 . Corrugated tape 26 and perforated plate 28 are preferably firmly connected to one another, for example by soldering.

On the perforated plate 28 is a closed mat 20 of rock wool, which is supported on its opposite side against another corrugated tape 30 , which in turn is attached to the lower wall 16 c of the protective jacket 16 . The corrugated strip 30 is formed directly from a perforated plate and also consists of aluminum.

In the left insulating section between the wall 12 b of the square tube 12 and the wall 16 b of the protective jacket 16 , the insulating jacket 20 consists of three spaced-apart web-shaped insulating strips 26 a running in the flow direction of the cooling air, which extend from the wall 12 b to the opposite wall 16 b run and form cavities 32 between them.

Of course, you will usually make a unitary insulation around the pipeline 10 . In this respect, the illustration only serves to describe different possible embodiments.

All constructive / geometric arrangements of the sound-absorbing outer insulating jacket 20 have in common that a gas and / or moisture passage (exchange) is guaranteed in all three spatial directions x , y , z .

Air and / or moisture can easily flow along the bead-shaped depressions 22 , the channels 24 , 24 a , 24 b , the corrugated bands 26 , 30 or the cavities 32 , with an exchange with the ambient atmosphere being made possible via the openings 18 . This enables the setting of an almost constant temperature profile between the vapor barrier 12 and the protective jacket 16 . In the event that, due to special influences, in spite of the condensed water, for example, should form on the outer surface of the vapor barrier 12 , this can be easily discharged to the outside in the manner described. This reliably prevents the soundproofing insulating jacket 20 from becoming wet.

The insulating arrangement according to the invention combines the advantages optimal thermal, especially cold insulation with those of a soundproofing.

Surprisingly, it has also been shown that, when the perforation of the outer protective jacket is written, ventilation is ensured even when the space between the vapor barrier 12 and protective jacket 16 is otherwise completely filled with a sound-absorbing insulating material. Soundproofing insulating materials of the type mentioned, such as mineral wool or the like, have the property of having an open porosity, via which air and / or moisture can also be exchanged even in the case of denser packagings, provided that - as the invention proposes - an exchange with the ambient atmosphere (here: through the openings 18 ). The clearances described in connection with the invention can then be seen in the individual pore spaces of the insulation.

The fire protection that forms the insulating layer described at the beginning Coating is shown on the four shown in the drawing presented design variants for example on the following Areas attached:

• - In the left insulating section on the lying between the insulating strips 20 a in the cavities 32 surfaces of the wall 12 b and / or the outer wall 16 b , if appropriate also on the surfaces 32 of the insulating strips 20 a facing surfaces.
• - In the upper insulating section on the surfaces of the United recesses 22 , in particular the inwardly directed recesses 22 and the insulating material 20 facing surfaces of the walls 12 a and 16 a .
• - In the right section on the surfaces of the walls 12 d or 16 d facing the insulating material 20 and / or the surfaces of the channel sections 24 a , 24 b .
• - In the lower section on the surfaces of the corrugated strip 26 facing the wall 12 c or the perforated plate 28 and / or on the surfaces of the corrugated strip 26 or the corresponding surfaces of the corrugated strip 30 or the wall 16 c .

Likewise, solid fire protection elements, for example Palusol panels, can be arranged, for example, between the pipeline 10 and the protective jacket 16 or between the vapor barrier 12 and the protective jacket 16 , which then preferably run in the plane of the drawing. The above-described rear ventilation is not disturbed because such fire protection plates are arranged at a distance from one another and between them the rear ventilation can take place in the manner described.

An essentially analog structure results in the Insulation of a pipe with a circular cross-section. At the above applies accordingly to wall insulation, then, for example, a vertical wall completely to the one shown in the drawing on the right Way can be isolated.

The sequence of individual sections of the Iso lieranordnung is easy, especially since a tightness in outer protective jacket is no longer necessary.

Claims (37)

1. Isolation arrangement for construction elements, characterized by a between the construction element ( 10 ) and a spaced protective sheath ( 16 ) with the formation of free spaces ( 22 , 24 , 24 a , 24 b , 26 , 30 , 32 ) angeord Neten, solid, sound-absorbing insulating jacket ( 20 ). 2. Insulating arrangement according to claim 1, characterized in that the insulating jacket ( 20 ) in the form of web-shaped, spaced apart, parallel to the structural element ( 10 ) and protective jacket ( 16 ) extending elements ( 20 a ) is formed. 3. Insulating arrangement according to claim 1, characterized in that the insulating jacket ( 20 ) in the form of web-shaped, spaced from each other and perpendicular between the construction element ( 10 ) and the protective jacket ( 16 ) extending elements. 4. Isolation arrangement according to claim 2 or 3, characterized characterized in that the elements one have a rectangular cross section. 5. Insulating arrangement according to claim 1, characterized in that the insulating jacket ( 20 ) surrounds this in a tubular construction element helically with the formation of a likewise helical free space between the individual sections of the helical insulation. 6. Insulating arrangement according to one of claims 1 to 5, characterized in that the insulating jacket ( 20 ) forms a first part of the overall insulation, the second part of which is the insulating jacket ( 20 ) adjacent, continuous insulating layer ( 14 ). 7. Insulating arrangement according to claim 6, characterized in that the insulating layer ( 14 ) adjacent to the construction element ( 10 ) and the insulating jacket ( 20 ) the outer protective jacket ( 16 ) be arranged adjacent. 8. Insulating arrangement according to claim 6 or 7, characterized in that between the insulating layer ( 14 ) and insulating jacket ( 20 ), a separating element ( 12 ) is arranged. 9. Insulating arrangement according to claim 8, characterized in that the separating element ( 12 ) is designed as a vapor barrier. 10. Insulating arrangement according to claim 8 or 9, characterized in that the separating element ( 12 ) consists of an aluminum or sheet steel. 11. Insulating arrangement according to one of claims 1 to 10, characterized in that the insulating jacket ( 20 ) is designed or arranged so that a gas and / or moisture penetration is preferably given in all three spatial directions. 12. Insulating arrangement according to claim 11, characterized in that the insulating jacket ( 20 ) extends at least partially at a distance from the outer protective jacket ( 16 ), the construction element ( 10 ), the separating element ( 12 ) and / or the insulating layer ( 14 ). 13. Insulating arrangement according to claim 11 or 12, characterized in that the insulating jacket ( 20 ) in the contact area to the protective jacket ( 16 ), to the construction element ( 10 ), to the separating element ( 12 ) and / or to the insulating layer ( 14 ) with recesses in sections ( 22 ) is formed. 14. Insulating arrangement according to one of claims 11 to 13, characterized in that between the insulating jacket ( 20 ), structural element ( 10 ), separating element ( 12 ), protective jacket ( 16 ) and / or insulating layer ( 14 ) one or more, ensuring air passage Spacers ( 26 , 30 ) is (are) arranged. 15. Insulating arrangement according to claim 14, characterized in that the or the spacer ( 26 , 30 ) is (are) designed corrugated sheet and are substantially parallel to the supporting components ( 12 , 16 ). 16. Insulating arrangement according to claim 14 or 15, characterized in that on the spacers ( 26 ) provided with openings flat sheets ( 28 ) rest and / or the spacers ( 30 ) themselves are formed with through openings. 17. Insulating arrangement according to claim 14, characterized characterized that the or the distance are designed as finite spacers and essentially perpendicular to the components supporting them run. 18. Isolation arrangement according to claim 17, characterized characterized that the spacers reduced in cross-section in its longitudinal extent are formed. 19. Insulating arrangement according to one of claims 1 to 18, characterized in that the outer protective jacket ( 16 ) has at least two spaced-apart air and / or moisture-permeable through openings ( 18 ). 20. Insulating arrangement according to claim 19, characterized in that the area of the through openings ( 18 ) with respect to the total area of the protective jacket ( 16 ) is <1%, preferably <0.5%. 21. Insulating arrangement according to claim 20, characterized in that the openings ( 18 ) are soundproofed. 22. Insulating arrangement according to one of claims 1 to 21, characterized in that the protective jacket ( 16 ) consists of an aluminum or steel sheet. 23. Insulating arrangement according to one of claims 1 to 22, characterized by forced ventilation in the region of the insulating jacket ( 20 ). 24. Insulating arrangement according to one of claims 1 to 23, characterized in that the insulating jacket ( 20 ) consists of an open-cell, sound-absorbing material. 25. Insulating arrangement according to claim 24, characterized in that the insulating jacket ( 20 ) made of mineral wool or an open-cell plastic foam, preferably a soft foam. 26. Insulating arrangement according to one of claims 1 to 25, characterized in that the insulating layer ( 14 ) consists of a closed-cell thermally insulating material. 27. Insulating arrangement according to claim 26, characterized in that the insulating layer ( 14 ) is a closed-cell plastic foam, preferably as a rigid foam or foamed glass. 28. Insulating arrangement according to one of claims 1 to 27, characterized in that the insulating layer ( 14 ) and / or the insulating jacket ( 20 ) relative to the components supporting them ( 10 , 12 , 16 ) by an interposed anti-drumming layer such as an anti-drumming cardboard, rubber or plastic insert is (are) soundproof. 29. Insulating arrangement according to one of claims 1 to 28, characterized in that the or the free spaces ( 22 , 24 , 24 a , 24 b , 26 , 30 , 32 ) delimiting surfaces are provided, at least in sections, with a fire protection coating which forms an insulating layer. 30. Insulating arrangement according to one of claims 1 to 29, characterized in that at least one in the or the free spaces ( 22 , 24 , 24 a , 24 b , 26 , 30 , 32 ) arranged spacers ( 26 , 30 ) at least in sections with a is provided under heat-insulating layer-forming fire protection coating. 31. Insulating arrangement according to claim 29 or 30, characterized in that the coated sections in the longitudinal direction of the structural element ( 10 ) are arranged at a distance from each other. 32. Isolating arrangement according to one of claims 29 to 31, characterized, that the intumescent coating from a foam layer-forming agent according to DIN 4102.   33. Isolation arrangement according to one of claims 29 to 32, characterized, that the intumescent fire protection coating an agent based on inorganic nitrogen ver bonds, carbohydrates, ammonium salts and / or more quality Al coal. 34. Insulating arrangement according to one of claims 29 to 33, characterized in that the coating is applied in such an amount that the corresponding free space ( 22 , 24 , 24 a , 24 b , 26 , 30 , 32 ) is completely filled under the influence of heat . 35. Insulating arrangement according to one of claims 1 to 34, characterized in that the insulating jacket ( 20 ) and / or the insulating layer ( 14 ) with perpendicular to the structural element ( 10 ) is arranged fire protection elements (are). 36. Insulating arrangement according to claim 35, characterized in that the fire protection elements are disc-shaped and in the longitudinal direction of the construction element ( 10 ) are formed at a distance from each other. 37. Isolation arrangement according to claim 35 or 36, characterized, that the fire protection elements so-called Palusol fire protection plates are.