DE202006001051U1 - Phase change material (PCM) insulation material for buildings - Google Patents

Abstract

insulating material (1) for the thermal insulation of buildings, in particular roofs and / or walls, with at least one carrier material (4, 10) and at least one connected to the carrier material (4, 10) Heat storage material (7) comprising at least one phase change material (PCM).

Description

The The invention relates to an insulating material for thermal insulation of buildings, especially from roofs and / or walls.

Consists between interior and exterior a building a temperature gradient, can heat by heat conduction, Convection and radiation transported from the warm to the cold side become. For insulation of buildings Different materials are used with the goal of heat transfer through the walls or the roof of the building to diminish. As a result, in winter, the heat transport from the interior to Outside and in summer the heat input from the outside inside as possible be prevented.

to Thermal insulation, that is called to hinder the transport of heat, insulation materials are used, the low thermal conductivity have, so the heat transfer by heat conduction in as possible small dimensions takes place. Furthermore, due to the structure of the thermal insulation materials the free space between the inside of the building and the outside so filled out, that the formation of air streams, what heat transmitted by convection, is prevented. Can do this Thermal insulation foams and Staple fibers, such as rock wool or glass wool, are used.

By the use of thermal insulation is the heat transport diminished and a temperature gradient upright receive. Especially with temperature fluctuations, for example between day and night and / or summer and winter, however, stands temporarily based on a desired Temperature too much, at times too little thermal energy available. In Times of high thermal energy is therefore cooled, in Times of low thermal energy heated. Heating and cooling in turn requires the use of energy and is therefore costly.

It Therefore, an object of the invention, a possibility arises for a Insulating material for thermal insulation of buildings to provide the energy surplus present in times of high thermal energy at least partly to harness in times too low thermal energy.

It a further object of the invention is to provide an insulating material, which is adaptable to existing structures. It is also one Object of the invention to provide an insulating material, which in a simple way on walls and / or on roofs can be moved.

These Tasks are solved by an insulating material for the thermal insulation of buildings, in particular roofs and / or walls, according to claim 1. Advantageous developments of the invention are Subject of the dependent claims.

The Invention provides an insulating material for thermal insulation of buildings, especially roofs and / or walls, with at least one carrier material and at least one with the carrier material connected heat storage material, which comprises at least one phase change material (PCM).

With Help of the heat storage material, which comprises a phase change material (PCM) makes it possible the invention, even in changing climatic conditions, for example due to the different seasons or the day / night rhythm To keep temperature fluctuations inside buildings as low as possible and thus the summer as well as the winter heat protection to improve.

Phase change materials, also latent heat storage called, are substances that absorb heat at a certain temperature or leave, without changing their own temperature. you calls this property "latent Heat storage " or delivered heat causes a change the state of aggregation of the phase change material, in the rules of firmly to liquid or vice versa. When storing heat in the form the so-called latent heat follows after reaching the phase transition temperature, this means usually the melting temperature, so long no change the temperature until the storage material is in its aggregate state Completely has changed, for example, completely melted. At the The latently stored heat, the enthalpy of fusion, solidifies delivered again.

Consequently can the energy surplus existing in times of high thermal energy in the form the enthalpy of fusion in the heat storage material, which includes, stores and stores a phase change material at least partially in times of low thermal energy again be delivered. The heat storage material damps In this way, temperature fluctuations and can be the training Reduce temperature gradient.

The insulating material according to the invention can be provided as insulating, in particular in the form of rolls and plates. In combination with the carrier material, the heat storage material advantageously can be easily adapted to existing structural structures. An advantageous embodiment of the invention is a sheet-shaped Isoliermate rial. In a preferred embodiment of the invention it is provided that the insulating material is flexible, so that it can be rolled up and thus stored in a particularly compact and easy to handle.

Around the heat storage effect of the insulating material to meet different requirements to be able to the invention provides in an advantageous development that the heat storage material a base material in which the phase change material is dispersed. The phase change material is in the form of Particles, for example in the form of balls, provided. About the Quantity and the type of selected Phase change material leaves the heat storage effect to adjust.

Around the advantageous flexibility of the insulating material, so that this rolled up, transported and can be stored and adapted to different forms of buildings can be, the invention provides that the base material as Coating applied to the substrate is. As a particularly suitable material for such a coating Acryl has been found. The base material can therefore be provided as an acrylic coating become. An acrylic coating, for example, by coating be created with a polyacrylate dispersion.

Around the thickness of the heat storage material in Choose a wide range variable to be able to It is advantageous, the phase change material in the form possible to provide small particles. In a preferred embodiment The invention provides that the phase change material in Shape of spheres with a mean diameter in the range of less than 30 μm, preferably in the range of greater than about 5 μm to less than about 20 microns, is present. In this size, the Particles of the phase change material easily in relatively thin coatings be involved. For example, the phase change material in the form of encapsulated spheres. The encapsulated balls can be one Have acrylic encapsulation.

In Such an encapsulation, the phase change material before changes its properties as a result of contact with the base material or other components of the insulating material.

In A further embodiment of the invention provides that the heat storage material at least one powdery one Phase change material includes. The particles of the powder phase change material can especially about be connected to a powder adhesive. The invention provides thus advantageously various ways ready, a heat storage material in to introduce a flexible, rollable web of insulating material.

in the for the Insulation or tempering of buildings interesting temperature range the invention provides that the phase change material at least a material from the class of paraffins includes.

Of the Phase transition from solid to liquid Paraffins may vary depending on which chemical structure used paraffin or the combination used of paraffins, has adjusted relatively accurately to the desired temperature range become. In addition, paraffins advantageously have a high enthalpy of fusion and therefore a big one Heat storage capacity.

One suitable carrier material for the Heat storage material can be provided for example in the form of a spunbonded fabric. In an advantageous embodiment of the invention, the insulating material at its in the installed state facing away from the building surface one Have reflective layer. In particular, this reflection layer on the heat storage material be upset.

Around the heat transfer through walls or roofs of buildings to further reduce and at the same time escape escaped To allow moisture is provided in an advantageous embodiment of the invention, that the insulating material at least a first reflection material and an insulation material having, wherein the insulating material spaced from the at least one first reflective material is, and thus a gap between the insulating material and the reflective material is trained. This will heat, which is transported by radiation through the insulating material, at the interface the gap to the reflective material at least partially reflected.

By the separation of the surfaces of insulation material and reflective material can improve the functionality of the reflective material be increased significantly. A heat transfer, in particular of the material absorbed and / or transmitted by the reflective material Part of the incident by radiation heat by conduction through the reflective layer adjacent materials, is reduced by the gap. The gap also offers the possibility of mass transfer, so that in the insulating material can escape penetrating moisture. In a preferred embodiment of the invention is the distance between thermal insulation material and the reflective material in the range of about 5 mm to about 20 mm.

In Another preferred embodiment of the invention comprises Insulating a spacer, which in the space is arranged to a minimum distance between the first reflection material and to comply with the insulation material. Spacers are constructed in the invention such that one possible big air entrapment is realized and as possible small contact area between Insulation material and the reflective material bearing surface is formed.

ever according to requirements of the application, in the context of the invention various materials are used as spacers. For example For example, the insulating material may comprise a knitted fabric as a spacer. The insulating material can also be profiled as a spacer Include material. Such a profiled material, for example a foamed Material which raises having. In the context of the invention, the insulating material as a spacer also comprising a spunbond deformed to form conformations. Suitable materials for the spacers are in particular thermoformable nonwovens or woven from, for example, polypropylene (PP) and / or polyamides (PA) and / or polyethylene terephthalate (PET).

When Insulating material can in the context of the invention, depending on the application, different materials with low thermal conductivity be used. In a preferred embodiment of the invention the insulating material as insulating material at least one microfiber nonwoven based on PE, PP and / or PET.

A Especially good thermal insulation can be used a microfiber web, which fibers with a fiber thickness in the range from 0.1 μm to 7 μm. To further improve the insulating ability of the insulating material, the insulating material with hollow balls, in particular with hollow balls of ceramic and / or Glass, be offset. Such hollow spheres are also referred to as "micro bubbles" Particularly preferred development of the invention provides as an insulating material microfibre fleece provided with micro bubbles.

In a further embodiment of the invention, the insulating material as insulating material a foamed Material comprising, for example, polyurethanes (PUR) and / or Polyethylene (PE) and / or PP and / or melamine resin. Especially are in the context of the invention as insulating material open-cell foams, if the vapor permeability of the network desired is, or, for vapor-proof composites, closed-cell foams from at least one of the mentioned materials, especially of melamine resin suitable. The insulation material is in a preferred embodiment according to the invention with a profiling provided, which takes over the function of the spacer. For example, such a profiled insulating material by accordingly shaped foams to be provided.

to particularly simple handling of the insulating material according to the invention, in particular also at the subsequent equipment of buildings with the insulating material and for variable adaptability to different Shapes like corners or protrusions of the building, is provided in the invention, the insulating material as to provide flexible, in particular rollable web. In a preferred embodiment of the invention comprises the insulating material at least one carrier web, in particular a sarking membrane for Roofs and / or Walls of Buildings.

Of the Heat transfer by the insulating material according to the invention can be further reduced by the carrier web one of the inside of the Insulating material facing first surface and one of the outside having the insulating material facing the second surface, wherein the carrier web at least on its first surface which comprises at least a first reflection material. The inside of the insulating material or the first surface of the carrier web point in the installed state of the insulating material to the building. The outside of the Insulating material or the second surface of the carrier web are installed in the Condition of the insulating material facing away from the building.

to further reduction of heat transfer by the insulating material, the carrier web at least at its second surface have a second reflection material, which heat radiation at least partially reflected. By on both sides of the carrier web a reflection material is attached, heat radiation can be reflected independently be, from which direction the heat radiation on the insulating material incident. This is particularly advantageous if the insulating material for buildings in areas is used in which in the course of the year, the temperature gradient through the walls or the roof of the building his direction changes.

In An advantageous development of the invention comprises the insulating material at least one further carrier web. For example the insulating material two carrier webs. Thus, the insulating material can be completed on both sides of a Unterspannbahn What, on the one hand, the thermal insulation material especially protects against mechanical wear and on the other hand, the handling of the insulating material improved.

In a further advantageous embodiment of the invention is provided that the at least one carrier web essentially permeable for water vapor is. For example, the insulating material according to the invention than in the built Condition outer layer a diffusion-open underlay with one or both sides Metallic vapor deposition include. The insulating material is thus advantageously executed open to the steam. Thus, in the insulating material penetrating moisture this leave essentially unhindered again. Moisture that in building parts can, which are in contact with the insulating material can pass through the insulating material. The insulating material Therefore hinders the drying of these components advantageously Not.

In particular, it is provided that the carrier web has a reflection material which has an S _d value of less than or equal to about 1 m. In an advantageous embodiment of the invention, the insulating material has on its inside a reflection material with an S _d value of less than or equal to about 1 m and on its outside a reflection material with an S _d value of less than or equal to about 0.1 m.

The S _d value is the so-called water vapor diffusion-equivalent air layer thickness and indicates - measured in m - how much denser than air is a substance against the migration of water vapor. In other words, a fabric having an S _d value of, for example, 0.1 m has a water vapor barrier value comparable to an air layer of 10 cm thickness. The larger the S value, the more vapor-tight is a substance. The S _d value is calculated from the multiplication of μ-number and the layer thickness s in m of a substance: S _d = μ × s.

When Reflective material can be the insulating material in a particularly simple Design include a metal layer. This can for example on the carrier web be evaporated. Suitable materials for the reflection material forming metal layer are aluminum and / or copper. Especially on the side facing away from the building in the installed state becomes a copper layer on the insulating material is preferred, with which Advantageously, the glare can be reduced. moreover Copper has a higher IR range Reflection effect which over it less of the wavelength depends as is the case with aluminum.

To the Protection against oxidation caused by moisture, oxygen and / or Heat causes can be in a preferred embodiment of the invention at least one of the reflective materials with an antioxidant be provided. As an antioxidant, for example, a Coating, a so-called coating, in the installed state from the building be applied away oriented reflection layer.

When Protective layer against oxidation, for example, a coating from transparent acrylic dispersion a so-called coating, on the in the installed state of the building be applied away oriented reflection layer. This acrylic dispersion coating is highly transparent in a preferred embodiment of the invention and very thin, preferably by the way it has a thickness of less than or equal to about 10 microns. With The aid of the coating can advantageously be a loss of the reflection effect be largely avoided.

In a further advantageous embodiment of the invention, the insulation material on its inside a barrier material. This barrier material may, for example, have a vapor-damping path. The term "vapor barrier" is understood here to mean a material which diffuses less water vapor than the underlay web arranged adjacent to the barrier material, meaning that vapor barriers are paths through which water vapor can not diffuse as far as possible, they have an S _d value of more than about 100 m.

The in the installed state room-side position of the barrier material has in particular a vapor barrier value in relation to which the barrier material subsequent Material, for example the outer side underlayment, of 6: 1 according to DIN 4108-3. Such still basically open to diffusion Execution can Room-side air humidity can diffuse outwards and makes the construction in terms of wood moisture damage and Heat losses through In the insulating material built-in moisture safely.

to Reflection of coming from the interior in the installed state thermal radiation the invention advantageously provides that the barrier material at its in the installed state facing the building a surface Reflection material, which heat radiation at least partially reflected. This reflection material can, for example, in the form an aluminum coating can be provided. A coating with an antioxidant, such as an additional Coating layer, is not essential here, as in the Usually a direct humidification on the inside does not occur.

Depending on the purpose of the insulating material this is provided in various dimensions, which are each adapted to the installation situation. The invention provides in particular that the insulating material has a width of up to about 3 m. This is especially suitable for Aufbrin conditions of insulating material on walls. For roof applications, a width of about 1.5 meters is preferred.

Around heat loss to avoid by convection, are in a preferred embodiment of Invention in the edge region of the insulating material at least the Insulating material to the outside limiting materials connected to each other so that they are Enclose the interior of the insulating material. For example, the Be welded edge of the insulating material.

in the Edge region of the insulating material may be a strip with less Thickness may be provided as the main area of the insulating material. Is the insulating material in several juxtaposed Used webs, this side strip can overlap in the edge area at the transition from to serve a train to the adjacent railway. This can advantageously the insulating material in a substantially completely closed area be moved. For quick and watertight installation can in Edge region of the insulating material to be provided an adhesive. Especially may be in the overlap area on the underside a self-adhesive strip be attached to the edge region.

The both lateral edge regions of the insulating material can in a preferred embodiment of the invention designed to complement each other be, so that at the same orientation of the insulating material webs the right edge area of a track complementary to the left edge area of the right adjacent railway is. Such a mutual welding leads advantageously about that increases in the overlap area be largely avoided. Transverse joints, overlaps, penetrations and connections can For example, with an aluminum tape air and waterproof accomplished become.

By the incorporation of phase change materials into an insulating material, which according to the invention flexible, in particular rollable, is, advantageously allows Heat in the heat storage material store reversibly. This can improve the effectiveness of the insulating material be improved in summer as well as in winter thermal protection. The vapor permeability and thermal conductivity of the insulating material are by the addition of phase change materials advantageously almost not affected.

The Inventive insulating material with its preferably vapor-permeable structure is advantageously can be integrated into existing buildings and thus particularly suitable for the renovation of old buildings. Furthermore is the insulating material as a supplement suitable for conventional thermal insulation. Energy losses by convection can be achieved by the insulating material according to the invention also be largely prevented. Due to the specific construction principle with spacing of reflective materials and insulation materials, the heat transfer becomes reduced in an advantageous manner. In addition, the inventive insulating material can be Easy, fast and clean installation, especially through the specific Design of the border areas.

Especially in its function as a thermal protection of inhabited spaces in winter the insulating material offers the advantage of having at least one reflection material to create a particularly pleasant indoor climate, as the proportion of Radiant heat in Room is increased by the reflection on the insulating material. It turned out provided that man needs about 60% of the heat supplied to him in the form of radiant heat to to feel comfortable. If the air in a room is only heated by heat conduction and convective heating, so the climate is not comfortable. By the insulating material according to the invention is the proportion of reflected heat, which as radiant heat to disposal stands, significantly increased, whereby also the heat radiated by humans is partially reflected.

The The invention will be described below with reference to the attached figures explained in more detail. the same Components are designated in all figures with the same reference numerals. Show it:

1 a schematic representation of a section of the insulating material according to the invention according to a first embodiment of the invention in section,

2 a schematic representation of a section of the insulating material according to the invention in a further embodiment of the invention in section,

3 a schematic representation of a section of the insulating material according to the invention in a further embodiment of the invention in section,

4 a photographic representation of a spacer according to an embodiment of the invention,

5 a photographic representation of a spacer according to another embodiment of the invention in top view,

6 a schematic representation of the in 3 shown spacer in bottom view,

7 a photographic representation of the insulating material according to the invention in a further embodiment of the invention in section,

8th a schematic representation of a section of the insulating material according to the invention in a further embodiment of the invention in section,

9 a schematic representation of a section of the insulating material according to the invention according to a further embodiment of the invention in section,

10 a schematic representation of a section of the insulating material according to the invention according to a further embodiment of the invention in section,

11 a schematic representation of a section of the insulating material according to the invention according to a further embodiment of the invention in section,

12 a schematic representation of a section of the insulating material according to the invention according to a further embodiment of the invention in section,

13 a schematic representation of a section of the insulating material according to the invention according to another embodiment of the invention in cross section,

14 a schematic representation of a section of the insulating material according to the invention according to a further embodiment of the invention in section,

15 a schematic representation of a section of the insulating material according to the invention according to a further embodiment of the invention in section,

16 a schematic representation of a section of the insulating material according to the invention according to a further embodiment of the invention in section,

17 a schematic representation of a section of the insulating material according to the invention according to a further embodiment of the invention in section,

18 a schematic representation of a section of a roof construction using the insulating material according to the invention according to the in 12 shown embodiment,

19 a schematic representation of a section of a roof construction using the insulating material according to the invention according to a further embodiment of the invention.

In 1 is a section of the insulating material 1 in its basic form shown schematically in section. The insulating material 1 may be an insulating element. In particular, the insulating material can be provided as a plate or as a material web. The insulating material 1 comprises a carrier material 10 and a heat storage material 7 ,

The heat storage material 7 includes a phase change material. Due to the enthalpy of fusion of the phase change material 7 can in the insulating material 1 penetrating heat can be stored. The temperature drops in the vicinity of the heat storage material 7 , the heat stored in the form of the latent heat of the phase transition, ie the enthalpy of fusion, is available in order to at least partially compensate the resulting temperature difference. The heat storage material 7 thus unfolds a buffer effect for temperature fluctuations.

In 2 is another embodiment of the heat storage material 7 in combination with a carrier material 10 shown. The heat storage material 7 has a base material 72 in which a phase change material 75 is dispersed in the form of spherical particles. It should be noted that the size ratios shown in the figures are not to scale. In particular, the balls are greatly enlarged in relation to the other dimensions drawn.

To also the heat transfer coefficient through the insulating material 1 to reduce is in 3 a further embodiment of the invention shown schematically, which is an insulating material 1 comprising a corresponding temperature fluctuation damper. The insulating material 1 includes a heat storage material 7 ,

In 3 is a particularly simple embodiment of an insulating material 1 shown which is a thermal insulation material 3 includes and a first reflective material 2 having. The reflection material 2 is from the insulation material 3 spaced apart. This will create a gap 23 educated. In the embodiment shown is a spacer 230 in the gap 23 arranged to the reflective material 2 from the insulation material 3 keep spaced. The insulating material 1 has an inside 11 which, when installed, faces the building. The outside 12 is facing away from the building when installed. On the outside 12 of the insulating material 1 is a heat storage material 7 in combination with the first Refle xionsmaterial 2 arranged.

As spacers different materials can be used. In 4 is a photograph of a PP / PA knitted fabric as an example 231 shown. These products are also called polymer structure mats. They have, for example, a thread thickness in the range of about 0.05 mm to about 2 mm and a basis weight in the range of about 50 g / m ² to about 500 g / m ² . They also have an irregular thread distribution.

Another example of a spacer is in the 5 and 6 shown. A PET / PP dome fleece is in 5 in top view and in 6 shown in bottom view. The Kalottenvlies has a substantially flat surface 232 , in which substantially hemispherical depressions (dome) are formed. In the view of the bottom 233 show the corresponding dome-shaped elevations. In particular, the elevations serve as spacers when the Kalottenvlies with its surface 232 on an insulation material 3 is hung up. The reflection layer 2 is then essentially with the bottom 233 the Kalottenvlieses in contact. The reflection layer 2 lies essentially at point-shaped contact points on the Kalottenvlies.

Just like the ones in the 4 to 6 Separating knitted fabrics and dome-shaped nonwovens can also be used to produce foams made in a profiled manner in order to produce the separation between the insulating material and the reflective layer. In 7 a photograph of a corresponding embodiment of the invention is shown. In contact with a vapor-permeable web, which is a reflection layer 2 has a profiled, cured foam 320 ,

In the example shown, this foam has two areas. A first region is formed by a substantially flat plate. On this plate ribs are applied in the second area. The ribs go over into the plate. On the top of the ribs is the reflection layer 2 at substantially linear contact points. The height of the ribs corresponds to the height of the gap 23 between the plate and the reflective layer 2 , The profiled foam 320 has a double function, namely, on the one hand, the insulating material 3 and on the other hand, as spacers 230 to serve. When using such a profiled foam 320 may advantageously be on a separate spacer 230 be waived.

In 8th is a further embodiment of the invention shown schematically, which is particularly suitable for winter heat protection. The insulating material 1 has a carrier. As a carrier becomes a sarking membrane 4 used. The underlay membrane 4 is vapor-open and aluminized on both sides to form the first reflection layer 2 and the second reflection layer 8th provide.

Furthermore, the underlayment has 4 on its outside 42 a second reflection material 8th and a heat storage material 7 on. The heat storage material 7 includes a basic material 72 in which a phase change material in the form of spheres 75 is dispersed on the heat storage material 7 is another reflection layer 9 appropriate.

The insulation material 1 further includes an insulating material 3 that of the first reflection layer 2 forming a gap 23 spaced apart. A distance switch 230 is in the space 23 to a minimum distance between the underlayment 4 with the first reflection layer 2 and the thermal insulation material 3 sure.

The insulation material 1 also includes a barrier material 5 , which at its in the installed state facing the building surface 51 another reflection layer 9 includes. The barrier material 5 with the further reflection layer 9 is designed as a room-side aluminized vapor barrier. The spacer 230 is formed by a Trenngewirke or separating fleece.

From the inside 11 on the insulating material 1 incident heat radiation is at the reflection layer 9 partially reflected, for example to 50%. The remaining part, for example 50%, at least partially reaches the interior of the reflection material 1 , On his way towards the outside 12 this fraction undergoes several interfaces between the different materials. In particular, when hitting the first reflection material 2 becomes a portion of the inside of the insulation material 1 reflected heat transported.

Likewise, a proportion of the heat, which from the reflective layer 2 out into the underlay 4 when hitting the second reflective layer 8th reflected. The heat that comes from the reflective layer 8th from the insulating material 1 leaves, is thus in the example considered significantly smaller than 25% of the interior on the inside 11 on the insulating material 1 incident heat radiation.

That of the first reflection material 2 inside the insulating material 1 reflected heat and at the second reflection layer 8th in the underlay membrane 4 reflected heat at least partially contributes to increasing the temperature of the underlayment 4 or the heat medämm material 3 of the air-filled gap 23 and the spacer 230 at. The course of the temperature gradient from the inside 11 to the outside 12 of the insulating material 1 is characterized by the inventive arrangement of the reflection layer or reflection layers in the direction of the outside 12 postponed.

In addition, the temperature fluctuations due to absorption or release of heat from the heat storage material 7 attenuated. By heat in the phase change material of the heat storage material 7 is stored, this latently stored heat is not absorbed by any of the other materials and therefore does not result in an increase in temperature due to the absorption. Therefore, it forms over the insulating material 1 with the heat storage material 7 a lower temperature gradient, so that, moreover, the driving slope for a heat transfer through the insulating material is lower than - for a material without a heat storage material 7 , Also, the insulation effect is significantly improved.

The heat storage material 7 for the insulating material 1 can also have its own carrier material 10 and thus as tempering with a composite of heat storage material 7 and carrier material 10 to be provided. Such a composite of a heat storage material 7 and a carrier material 10 is in 9 in combination with a composite of a thermal insulation material 3 and a reflective material 2 shown.

In 10 is another embodiment of a composite material of a tempering 7 . 10 with an insulating material which is a heat storage material 7 and from an insulation material 3 spaced-apart reflection materials 2 includes shown.

The insulating material 1 According to this further embodiment of the invention comprises a thermal insulation material 3 , which on both sides over spaces 23 of reflective materials 2 . 9 is arranged spaced apart is respected. The reflection materials 2 . 9 are as a coating on underlays 4 applied. The outside 12 of the insulating material 1 facing underlayment 4 has reflective materials on both sides 2 . 8th on. On both sides with reflective materials 2 . 8th provided underlay membrane 4 a tempering material is applied, which is a carrier material 10 and a heat storage material 7 includes.

The heat storage material 7 is in the form of a coating of a base material 72 on the carrier material 10 applied. In the basic material 72 are particles of a phase change material 75 dispersed. The phase change material 75 is provided in the form of balls. The inside 11 facing underlay membrane 4 is room side with a reflection layer 9 Mistake. Except the spacer 230 there is also this underlay 4 in the gap 23 between the insulation material 3 and the reflective material 9 ,

On the heat storage material 7 is to the outside 12 of the insulating material 1 towards another reflection layer 9 applied. A suitable material for the reflective materials 2 . 8th . 9 such an insulating material 1 is in particular aluminum. The outside reflection layer 9 is as a coating on the heat storage material 7 applied (coated). On the spunbond, which as a carrier material 10 An acrylic coating is applied as a base material 72 serves. In the acrylic coating 72 are microencapsulated paraffin balls 75 dispersed with an acrylic encapsulation. As insulation material 3 an insulating fleece is used. Adjacent to the Dämmvlies 3 are Trenngelege 230 in the insulating material 1 brought in.

In the in 11 represented further embodiment of the invention is the heat storage material 7 on the outside arranged underlay membrane 4 positioned. The room side has the insulating material 1 a barrier material 5 on, at its in the installed state room-side, that is to the inside 11 facing surface 51 another reflection material 9 wearing.

Except the spacer 230 there is also this underlay 4 in the gap 23 between the insulation material 3 and the reflective material 9 , The reflection material on the room side 9 from the thermal insulation material 3 forming a gap 23 arranged so spaced that heat conduction at the junction of the thermal insulation material 3 to the reflection material 9 can be substantially completely prevented.

In the in 12 schematically illustrated embodiment is the insulating material 1 with respect to a central plane through the insulating material 3 symmetrically constructed and on the outside with a carrier web 10 connected to the a heat storage material 7 as a coating in the form of a base material 72 is appropriate. In the basic material 72 are spherical particles of a phase change material 75 dispersed. On the heat storage material 7 is a reflective coating 9 appropriate.

At the insulation material 3 close on both sides spaces 23 at. In the intervals 23 are spacers 230 arranged to a minimum distance between the insulation material 3 and the reflective layers. The insulating material 1 becomes to its outside 12 as well as to its inside 11 each through a roofing membrane 4 completed. The underlays 4 show at their first surfaces 41 a first reflection material 2 and on their second surfaces 42 a second reflection material 8th on.

In addition to the basis of in 8th illustrated embodiment shown for winter heat protection is suitable in 12 illustrated embodiment also particularly good for summer heat protection. For one from the outside 12 on the insulating material 1 occurred heat flow can be analogous to the approach described above for in 8th shown embodiment is shown, that the proportion of the outside 12 from impinging heat radiation through the insulating material 1 over the inside 11 delivered to the building, can be well below 25%. This is made possible in that, in particular, the reflection at the distance from the thermal insulation material 3 arranged first reflective layer 2 and second reflection layer 8th against an arrangement of these reflection layers in direct contact with the thermal insulation material 3 can be increased.

The heat storage material buffers 7 with the phase change material 75 the amount of heat corresponding to the enthalpy of fusion of the total mass of the phase change material used. Thus, temperature fluctuations are reduced.

In 13 is an insulating material 1 represented according to a further embodiment of the invention in cross section. From the inside 11 to the outside 12 of the insulating material 1 considered, includes the insulating material 1 a reflection layer 9 pointing to a barrier material 5 is applied. The barrier material 5 is in contact with an insulation material 3 , which forms a gap 23 spaced from a first reflective layer 2 a sarking membrane 4 is arranged. A spacer 230 sets the distance between the reflection material 3 and the first reflection layer 2 in the main area of the insulating material 1 for sure. The underlay membrane 4 has a second reflection material 8th at the outside 12 of the insulating material 1 on the surface. On top of that is a heat storage material 7 applied comprising a phase change material. On the heat storage material 7 is another reflection material 9 arranged.

The insulating material 1 has a border area 13 , This edge region has one opposite the main region of the insulating material 1 reduced thickness. In the border area 13 stand the materials of the insulating material - namely reflection layer 9 , Barrier material 5 , Insulation material 3 , Reflection layer 2 , Carrier web 4 , Reflection layer 8th Heat storage material 7 and relfexion coating 9 - in communication with each other and are closed to each other by welding the reflective layers together. The border area 13 is underside with a glue 6 Mistake.

In the in 13 Example shown is on the right side of the picture in the picture of the insulating material 1 a border area 13 shown. The top of this edge area 13 is as an area with the outside 12 of the insulating material 1 educated. According to the in 12 illustrated embodiment of an edge region 13 the insulating material can also on the edge region shown 13 opposite left side have a complementary edge region.

Such a complementary edge region is mirror-inverted to that in FIG 12 shown border area 13 constructed and includes on its top an adhesive 6 , Its bottom is considered an area with the inside 11 of the insulating material 1 educated. At one of the mutually complementary edge areas may be on the adhesive 6 be waived. Webs of insulating material 1 with mutually complementary edge regions 13 can be subsequently laid side by side, with the mutually complementary edge areas 13 overlap each other and over the glue 6 connected to each other. By connecting a plurality of webs of the insulating material 1 to each other can advantageously substantially flat outer surfaces 12 and inner surfaces 11 be realized because of the correspondingly reduced thickness of the edge regions 13 an increase in the area of the connection of adjacent insulating materials is avoided.

The advantage of the latent heat storage and an increased reflection effect on in the interior of an insulating material 1 arranged reflective materials by maintaining distances 23 to the adjacent layers can be used in the context of the invention in further going multi-layer structures. Exemplary is in 14 an insulating material 1 according to another embodiment of the invention, in which on the outside a on a carrier web 10 applied heat storage material 7 is arranged, which is a reflection layer 9 wearing. Between the outside 12 and the inside 11 are two layers of thermal insulation material 3 intended. Each layer of thermal insulation material 3 is under formation of a gap 23 arranged to the respective adjacent layer. The gaps 23 include spacers 230 ,

Outwardly, the insulating material 1 by the underlay membrane 4 on the inside 11 and by the reflective coated heat storage material 7 with phase change material 75 on the outside 12 completed. In the embodiment shown, the underlayment is 4 on the inside 11 of the insulating material 1 room side with a reflection layer 2 Mistake. The outer underlay 4 is on both sides with reflection layers 2 . 8th Mistake.

Between that to the outside 12 on the inside 11 pointing thermal insulation material 3 arranged spacers 230 and to the inside 11 towards the outside 12 arranged spaced thermal insulation material spacers 230 is one of spacers 230 surrounding reflection layer 2 arranged. Especially at this middle reflection layer 2 can be both from the outside 12 of the insulating material 1 as well as from the inside 11 of the insulating material 1 incident heat radiation are reflected particularly efficiently.

In 15 is another embodiment of the insulating material 1 shown, which is particularly well suited for use in old building renovation. The inner side and outer side have the same S _d value in this embodiment, as a result of which any possibly existing and unknown defects of the air seal can be compensated for on the room side.

On its inside 11 has the insulating material 1 a diffusion-open underlay membrane 4 with an S _d value of less than 0.1 m. The underlay membrane 4 is with a reflective layer 2 Mistake. Between the reflection layer 2 and a first thermal insulation material is a gap 23 with the help of a spacer 230 respected. As spacers, a separating layer and / or a separating grid and / or a separating fleece can be used.

The first thermal insulation material is a vapor-permeable melamine resin foam 32 , which by means of a spacer 230 under formation of a gap 23 from a reflection layer 2 spaced apart. The reflection layer 2 is on a substantially in the middle of the insulating material 1 located vapor-permeable underlay membrane 4 appropriate. This underlayment further comprises a second reflective layer 8th from which a second insulation material is spaced 31 is arranged.

As second insulation material 31 is a diffusion-open PET fleece used. Distanced from the PET nonwoven 31 is another diffusion-open underlay membrane 4 arranged with an S _d value of less than 0.1 m. On this is a reflection material 8th appropriate. On top is a coating of a base material 72 applied, in which a phase change material 75 is dispersed. This carries another reflection material 9 and closes the insulating material for the application in the old building renovation to the outside 12 down.

In 16 is another embodiment of the insulating material 1 shown, which is particularly suitable for use in new construction in roof and wall. In the new building, the airtightness is defined on the room side and controlled - for example, by means of a so-called blower door measurement - carried out, whereby an increased moisture load by convection can be largely excluded. Unlike the in

15 shown insulating material for use in the Altbausanierung has the insulating material 1 for use in new construction to the inside 11 towards a vapor-permeable vapor barrier 5 with an S _d value of less than or equal to about 1 m.

The vapor-permeable vapor barrier 5 is on her inside 11 indicative surface with a reflective layer 2 Mistake. As for the inside 11 The facing insulating material is a vapor-permeable melamine resin foam / PUR foam 33 used. To the outside 12 there is a carrier web 10 arranged. On top is a coating of a base material 72 applied, in which a phase change material 75 is dispersed. This carries another reflection material 9 and closes the insulating material 1 to the outside 12 down.

In 17 is another embodiment of the insulating material 1 shown, which is particularly inexpensive. Unlike the in 16 shown insulating material has the most cost-effective insulating material 1 in the middle as another reflection material 9 a wavy aluminum foil on. It can also be a correspondingly profiled web of paper can be used, on which aluminum foil is applied. For example, a lattice-reinforced and corrugated composite of paper and aluminum can be used.

In 18 is an example of an installation situation of the insulating material according to the invention 1 shown. Between rafters 100 there is an internal wall or roof insulation 120 , For isolation 120 For example, a mineral fiber material having a thickness of 100 to 150 mm can be used. To the interior of the building there is a room-side paneling 130 , On the side of the rafters facing away from the building 100 is the insulating material 1 applied. In the application example shown is an insulating material 1 The inside shows vapor-permeable underlays 4 with a S _d value of less than or equal to about 0.1 m in the form of a highly open-diffusion cover. The underlays 4 are each on both sides with reflection layers 2 . 8th Mistake.

To the outside 12 there is a carrier web 10 arranged. On top is a coating of a base material 72 applied, in which a phase change material 75 is dispersed. This carries another reflection material 9 and closes the insulating material 1 to the outside 12 down.

The diffusion-open design is particularly important, but not only in the renovation of old buildings, so as not to hinder the dehumidification of the building by diffusion of water vapor to the outside. Both from the rafters 100 as well as from the room side through the room-side paneling 130 and the internal wall or roof insulation 120 Through it, water vapor can diffuse through the insulating material 1 be transported. This transport of water vapor is by arrows 140 in 15 shown schematically. The great advantage of this use of the insulating material according to the invention is that a doubling of the rafters is eliminated and thus time and costs can be saved. The Althausbestand has roofs with usually a rafter height of about 100 mm to a maximum of 120 mm. In order to meet the requirement of, for example, in Germany currently valid heat insulation regulations, this height would have to be set to at least 150 mm in order to bring additional insulation wool can. The process of rafter elevation is called doubling.

In 19 is another example of an installation situation of the insulating material according to the invention 1 shown. Unlike the in 16 illustrated embodiment is between the rafters 100 no internal wall or roof insulation arranged. The thermal insulation is in this example solely by the insulating materials 1 reached, one of which on the outside, and one inside on the rafters 100 is appropriate. The space between the rafters, which of the two layers of insulating materials 1 is limited, it is not ventilated. By combining a room-side layer of an insulating material 1 with an outside layer of an insulating material 1 In this case, a conventional insulation can be replaced.

In the old building renovation offers the insulating material according to the invention 1 in addition to the renouncement of the doubling of the rafters and the free water vapor diffusion to the outside air and thus the moisture-technically safe construction the advantage, by the employment of a reflective underlay with thermal insulation on additional mineral wool 120 or to dispense with additional other constructive measures. In addition, the isolation of the invention 1 without ventilation and thus be installed windproof. This cools the inner wall or roof insulation 120 not enough, and heat losses can be further minimized.

Furthermore, the inventive insulating material can be 1 move quickly, easily and safely. In addition to the renovation of old buildings pitched roofs are both in new construction as well as redevelopment floors, facades in timber stand construction and / or masonry and floors other applications for the invention. The term "wooden stand construction" in contrast to the masonry wooden houses meant in which the supporting parts roof and wall are made of wood.

It It will be apparent to those skilled in the art that the invention is not limited to the above described embodiments limited is, but rather in more diverse Way can be varied. In particular, the characteristics of each embodiments also be combined with each other.

1

insulating material

11

Inside, when installed, the building facing surface of the insulating material

12

Outside, when installed, the building opposite surface of the insulating material

13

border area of the insulating material

2

first reflecting material

8th

second reflecting material

9

third, further reflection material

3

Insulating material

31

diffusion-open PET nonwoven

32

diffusible Melamine resin foam

33

diffusible Melamine resin foam / PU foam

23

gap

230

spacer

231

PP / PA Knitted

232

PET / PP domed nonwoven in top view

233

PET PP domed nonwoven in bottom view

320

profiled, foamed material

4

Support web Underlayment

41

first - in the built-in Condition of the building facing - surface of support web

42

second - in the built-in Condition of the building opposite - surface of support web

5

barrier material

51

in the built-in state of the building facing surface of the barrier material

6

Glue

7

Heat storage material

72

base material

75

Phase change material (PCM)

10

support material

100

rafter

120

internal Wall or roof insulation

130

interior side paneling

140

transport of water vapor

Claims (38)

Insulating material ( 1 ) for the thermal insulation of buildings, in particular roofs and / or walls, with at least one support material ( 4 . 10 ) and at least one with the carrier material ( 4 . 10 ) associated heat storage material ( 7 ) comprising at least one phase change material (PCM). Insulating material ( 1 ) according to claim 1, characterized in that the insulating material ( 1 ) is flexible, in particular rollable. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the heat storage material ( 7 ) a basic material ( 72 ) in which the phase change material ( 75 ) is dispersed. Insulating material ( 1 ) according to claim 3, characterized in that the base material ( 72 ) as a coating, which in particular comprises acrylic, on a carrier material ( 4 . 10 ) is applied. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the phase change material ( 75 ) in the form of spheres having a mean diameter in the range of less than 30 microns, preferably in the range of greater than 5 microns to less than 20 microns. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the phase change material ( 75 ) in the form of encapsulated spheres. Insulating material ( 1 ) according to claim 6, characterized in that the encapsulated spheres have an acrylic encapsulation. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the heat storage material ( 7 ) at least one powdered phase change material ( 75 ). Insulating material ( 1 ) according to claim 8, characterized in that the particles of the powder phase change material ( 75 ), in particular via a powder adhesive, are interconnected. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the phase change material ( 75 ) comprises at least one material from the class of paraffins. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the carrier material ( 4 . 10 ) comprises a spunbonded web. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the insulating material ( 1 ) on its surface facing away from the building in the installed state ( 12 ) a reflection layer ( 9 ) having. Insulating material ( 1 ) according to claim 12, characterized in that the reflection layer ( 9 ) on the heat storage material ( 7 ) is applied. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the insulating material ( 1 ) at least one reflection material ( 2 ) and an insulating material ( 3 ), wherein the insulating material ( 3 ) of the first reflection material ( 2 ) is spaced apart, wherein a gap ( 23 ) is formed, so that heat, which by radiation through the insulating material ( 3 ), at the interface of the interspace ( 23 ) to the reflective material ( 2 ) is reflected at least partially. Insulating material ( 1 ) according to claim 14, characterized in that the insulating material ( 1 ) a spacer ( 230 ), which in the space ( 23 ) is arranged to maintain a minimum distance between the first reflection material ( 2 ) and the insulating material ( 3 ). Insulating material ( 1 ) according to claim 15, characterized in that the spacer ( 230 ) a knitted fabric ( 231 ). Insulating material ( 1 ) according to claim 15 or 16, characterized in that the spacer ( 230 ) a profiled material ( 320 ). Insulating material ( 1 ) according to one of Claims 15 to 17, characterized in that the spacer has a spunbonded non-woven fabric ( 232 . 233 ). Insulating material ( 1 ) according to one of Claims 15 to 18, characterized in that the spacer comprises PP and / or PA and / or PET. Insulating material ( 1 ) according to one of claims 14 to 19, characterized in that the insulating material ( 3 ) comprises at least one microfiber nonwoven based on PP and / or PET. Insulating material ( 1 ) according to claim 20, characterized in that the microfibrous web comprises fibers having a fiber thickness in the range of 0.1 microns to 7 microns. Insulating material ( 1 ) according to one of claims 14 to 21, characterized in that the insulating material ( 3 ) is mixed with hollow spheres, in particular of ceramic and / or glass. Insulating material ( 1 ) according to one of claims 14 to 22, characterized in that the insulating material ( 3 ) comprises at least one foamed material comprising PUR and / or PE and / or PP and / or melamine resin. Insulating material ( 1 ) according to one of the preceding claims, characterized by at least one first carrier ( 4 ), which comprises a roofing membrane for roofs and / or walls of buildings. Insulating material ( 1 ) according to claim 24, characterized in that the first carrier ( 4 ) the first reflection material ( 2 ). Insulating material ( 1 ) according to claim 24 or 25, characterized in that the first carrier ( 4 ) a second reflection material ( 8th ), which reflects heat radiation at least partially. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the insulating material ( 1 ) a second carrier ( 4 ), in particular a roofing membrane for roofs and / or walls of buildings. Insulating material ( 1 ) according to one of claims 23 to 27, characterized in that at least one of the supports ( 4 ) is substantially permeable to water vapor. Insulating material ( 1 ) according to one of claims 13 to 28, characterized in that at least one of the reflection materials ( 2 . 8th . 9 ) comprises a metal layer. Insulating material ( 1 ) according to claim 29, characterized in that the at least one reflection material comprising a metal layer ( 2 . 8th . 9 ) on one of the supports ( 4 ) is evaporated. Insulating material ( 1 ) according to claim 29 or 30, characterized in that the metal layer comprises aluminum and / or copper. Insulating material ( 1 ) according to one of claims 13 to 31, characterized in that at least one of the reflection materials ( 2 . 8th . 9 ) is provided with an antioxidant. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the insulating material ( 1 ) on its inside ( 11 ) a barrier material ( 5 ), which is substantially impermeable to water vapor. Insulating material ( 1 ) according to claim 33, characterized in that the barrier material ( 5 ) a vapor barrier value in relation to which the barrier material ( 5 ) adjoining material according to DIN 4108 of 6: 1. Insulating material ( 1 ) according to claim 33 or 34, characterized in that the barrier material ( 5 ) in its installed state facing the building surface ( 51 ) a reflection material ( 9 ), which reflects heat radiation at least partially. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the insulating material has a width of up to 3 m. Insulating material ( 1 ) according to one of the preceding claims, characterized in that in the edge region ( 13 ) of the insulating material ( 1 ) at least the insulating material ( 1 ) bounded to the outside materials and the interior of the insulating material ( 1 ) enclose. Insulating material ( 1 ) according to one of the preceding claims, characterized in that the insulating material ( 1 ) in particular in the edge region an adhesive ( 6 ).