EP4239140A1 - Water-storing underlay - Google Patents

Abstract

The invention relates to an underlayment (U) which is permeable to water vapor but impermeable to liquid water and has an outward-facing cover layer (1) when laid on a roof or wall and an inward-facing inner layer (7). In order to prevent liquid water from accumulating on the inner layer (7) when the air humidity is high indoors, the inner layer (7) is a water-absorbing storage layer (7) which can absorb liquid water during the high air humidity and from which the liquid Water can evaporate at reduced humidity.

Description

field of technology

The invention relates to an underlay which is laid on a roof or a wall under a roof covering or a wall cladding and which, when laid, has a cover layer which points outwards and an inner layer which points inwards. Such an underlay is impermeable to liquid water but permeable to water vapor. This property is typically achieved with a functional layer that is a microporous film.

State of the art

From the DE 199 04 423 A1 such a roof underlay is already known. A cover web is bonded to a microporous film with a thermoplastic hot-melt adhesive. The latter is supported by a base fleece which, when laid, faces inwards, i.e. towards the wall or the roof substructure.

In addition, other multi-layer underlays are already known from the prior art, in which polyester nonwovens or polypropylene nonwovens are used as the top and bottom layers.

There are also underlays that are coated with a permeable and waterproof polyacrylate dispersion or with polyurethane. This makes it possible, for example, to achieve high UV resistance.

Furthermore, it is known to arrange an intermediate layer of a meltblown nonwoven between a cover nonwoven and a base nonwoven.

The problem with the prior art, where the bottom layer is hydrophobic, is that in cold weather, moisture can condense on the underside of the underlayment. Droplets can form, which can run down the underside, collect in large quantities and thus contribute to mold growth.

Summary of the Invention

The invention is based on the object of proposing measures with which the aforementioned disadvantages are eliminated.

The object is achieved by the invention specified in the claims. The subclaims not only represent advantageous developments of the invention specified in claim 1, but also independent solutions to the problem.

First and foremost, it is proposed that the inner layer be capable of absorbing water. The inner layer can thus form a storage layer that is able to temporarily store liquid water when water vapor condenses on the underlay due to a cold roof underlay and high humidity on the inside. The water can remain stored in the inner layer until it can diffuse outwards through the underlayment after a change in the thermodynamic environmental properties. According to a preferred embodiment, the storage layer can be a spunbonded nonwoven or a staple fiber nonwoven. The storage layer can be made of polypropylene or polyester. In particular, it is provided that the storage layer has a storage capacity for water of more than 300 g/m ² . In addition, the storage layer can have a tear strength of at least 200 N/50 mm. While the inner layer is preferably hydrophilic, the outer layer can be hydrophobic. The cover layer can be formed from a fleece. It can be a consolidated polypropylene spunbonded nonwoven. Because the top layer is preferably hydrophobic, the underlay has a water-repellent surface that does not absorb water when it rains, but lets it roll off. The top layer can (also) be equipped with hydrophobic additives to further increase the water-repellent property. This also provides additional resistance to surfactants. The top layer, like the inner layer, is permeable to water vapour. In a preferred embodiment, the underlay has a functional layer that is impermeable to liquid water but permeable to water vapor. The functional layer can be a microporous film, which consists in particular of polyolefin, preferably of polypropylene. The film can have a thickness of 25 to 40 g/m ² . The microporous film can consist of 40% to 60% calcium carbonate. In particular, it has calcium carbonate particles with a particle size in the micrometer range. By stretching this polyolefin film in at least one direction during production, microscopic pores form in the area of the calcium carbonate particles. The sd value of the functional layer can be 2 to 10 cm. However, the sd value can also be greater and in particular significantly greater, for example at least 1 m. In a further development it can be provided that there is a further layer between the functional layer and the cover layer, which layer also consists of polyolefin. It can be a meltblown fleece that has a thickness of 20 to 40 g/m ² . This intermediate layer can be rendered hydrophobic by means of fluoropolymers. This increases the waterproofness. This intermediate layer is also characterized by increased stability against aging. In addition, it can have high UV stability. For this purpose, suitable substances, such as carbon black or the like, can be added to the intermediate layer. The top layer can also have components that increase the UV stability. This increases the outdoor exposure time to up to 6 months and the durability to at least 20 years. The individual layers can be connected to one another by means of an adhesive lamination. The adhesive is preferably applied porous between the layers of the underlayment. This reduces the hindrance of water vapor diffusion through the underlay.

According to a development of the invention, which also has an independent character, it is proposed that the bottom layer in the laid state has an edge that is set back compared to the edge of the underlayment. The edge of the inner layer, which can also be a storage layer, is thus spaced apart from the edge of the overlying layer, so that a narrow strip directly adjoining the edge of the underlay membrane is not covered with the inner layer. The width of this overhang can be between 5 mm and 150 mm. When laying several underlays next to each other, an edge area of one underlay is placed on an edge area of another underlay so that an overlap occurs. The excess free from the inner layer preferably forms such an overlapping area. If the inner layer has a hydrophilic property, ie is able to absorb water, this overlapping area free of the inner layer prevents rainwater from coming from the outside through the overlapping area into the inner layer. This feature reduces the risk of rainwater entering the bottom layer laterally over the edge when the bottom layer has a high water absorbency. The edge area free of the storage layer thus forms a transport barrier. The absorbency of the bottom layer allows liquid water to be trapped in the tiny spaces between the fibers. Through capillary effects and interface effects Basically, liquid water can also be transported on the fibers in the direction of surface extension. The free edge area forms a barrier for this transport.

According to a further development of the invention, which also has an independent character, it is proposed that the underlayment has adhesive strips and in particular self-adhesive strips. These adhesive strips are attached along the longitudinal edge of the web. They extend in the area near the edge and in particular directly adjacent to the edge of the underlayment. A first adhesive strip can be provided, which is arranged in the area near the edge on the underside of a first edge. A second adhesive strip can be provided, which is arranged in the area close to the edge on the upper side of a second edge and which can come into an adhesive connection with the first adhesive strip of an adjacent underlay membrane. This further development is particularly advantageous when the underlayment has an edge area which, as described above, has no storage layer in the area near the edge. The adhesive strip can then be applied directly, at least in regions, to the layer arranged above the storage layer, which layer is in particular a functional layer. Provision can also be made for the width of the adhesive strip to extend beyond the edge of the storage layer, so that the adhesive strip is applied both to the functional layer and to the storage layer. The width of the adhesive strip can be between 200 and 800 mm. This adhesive strip is preferably positioned in such a way that it partially adheres to the fleece pointing downwards and partially to the next higher layer, which is formed in particular by the functional layer. This seals the edge of the storage layer with the adhesive on the tape strip to prevent water from getting in from the side. The second adhesive strip, which is on the outside of the underlayment, is applied to the top layer. Both adhesive strips are preferably strips that are adhesive on both sides. When laying the The two adhesive strips are placed one on top of the other so that they stick to each other in a windproof and waterproof manner. An adhesive connection is preferably formed between the adhesive strips, which cannot be separated without being destroyed.

As a result of the design of an underlayment according to the invention, it receives a further functional mechanism with which condensation moisture that occurs in very cold weather can be counteracted. If the amount of water accumulating due to condensation on the underside of the underlayment becomes so large that it can no longer diffuse from the inside to the outside, it is absorbed and held by the storage layer, which is in particular made of a fleece, until the environmental conditions change in such a way that the moisture can be transported through the underlay so that it can evaporate on the outside of the underlay. By storing liquid water in the inner layer, water droplets that can run down the film are prevented from forming.

Brief description of the drawings

Fig. 1

schematisch einen bereichsweise freipräparierten Abschnitt einer Unterspannbahn,

Fig. 2

schematisch einen Schnitt durch die Unterspannbahn eines ersten Ausführungsbeispiels,

Fig. 3

schematisch einen Schnitt durch eine Unterspannbahn eines zweiten Ausführungsbeispiels,

Fig. 4

schematisch einen Schnitt durch eine Unterspannbahn eines dritten Ausführungsbeispiels und

Fig. 5

das dritte Ausführungsbeispiel, bei dem zwei benachbarte Dachunterspannbahnen miteinander verklebt sind.

Exemplary embodiments of the invention are explained using the accompanying drawings. Show it:

1

schematic of a partially prepared section of an underlay membrane,

2

schematically a section through the underlay of a first embodiment,

3

schematically a section through an underlay of a second embodiment,

4

schematically shows a section through an underlayment of a third embodiment and

figure 5

the third embodiment in which two adjacent roof underlay sheets are bonded together.

Description of the embodiments

The in the Figures 1 to 4 The roof underlays shown are used as construction plans. When cladding a wall, they can be applied to battens or another substructure 8 . In the case of a roof construction, the roof underlay U can be applied to a roof substructure. This is done in the form of several adjacent tracks that overlap at their edges. Some exemplary embodiments are designed in such a way that adjacent webs can be glued to one another in the region of their overlap, for which purpose adhesive strips 11, 12 are provided. The roof underlay U can also perform the function of a makeshift cover. They keep the roof truss dry as long as the actual roof covering has been applied to the roof underlay. During this time, the roof underlays drain away rainwater.

However, the main task of the roof underlay is to provide additional sealing of the roof or wall against the ingress of liquid water and to allow water vapor to escape from the building. If the indoor air humidity is high and the roofing membrane is cold, the transport capacity of the roofing membrane for vaporous water cannot sufficient to allow water vapor to condense on the inside of the cold roof underlay. With prior art roofing underlays, droplets can form which can run down the roofing underlay when the roofing underlay is inclined. They can drip off the roof underlay or collect elsewhere. This brings the risk of mold growth.

The roofing underlay U according to the invention has a storage layer 7 which points inwards when laid and which is able to absorb liquid water.

The figure 2 shows a first exemplary embodiment of such a roof underlay membrane, in which a covering layer 1 lying opposite the barrier layer 7 is a spunbonded nonwoven. It can be a bonded and in particular thermally bonded polypropylene spunbonded nonwoven. The top layer 1 is water-repellent, so that the roof underlay has a water-repellent, outward-facing surface that does not absorb water in the event of rainwater ingress. Rather, the water rolls off the top layer. However, the top layer can also be equipped with hydrophobic additives, so that the water-repellent property is increased. The cover layer, like all layers explained further below, is permeable to water vapor.

The cover layer 1 is connected to an intermediate layer 3 with a porous adhesive layer 2 or by means of thermal or ultrasonic calenders. The adhesive layer 2 is designed in such a way that it has little or no blocking effect against the passage of water vapor.

The intermediate layer 3 can be a meltblown fleece. The intermediate layer can have a thickness of between 20 and 40 g/m ² . The intermediate layer can consist of polypropylene or another polyolefin. The intermediate layer 3 can additionally be rendered hydrophobic by means of fluoropolymers. With this additional finish, the intermediate layer becomes impervious to liquid water, but remains permeable to water vapour. In addition, the intermediate layer 3 can also contain additives that increase the UV stability.

The intermediate layer 3 is also connected to a functional layer 5 with a porous adhesive layer 4 or by means of thermal or ultrasonic calenders. As an adhesive layer, it can have the same properties as the adhesive layer 2 .

The functional layer 5 is permeable to water vapor but blocks the passage of liquid water. The functional layer can be a thin film. The thickness of the functional layer can be 25 to 40 g/m ² . The functional layer 5 can be made of polypropylene or another polyolefin. The water vapor permeability can be achieved by stretching a previously produced film. For this purpose, the foil contains calcium carbonate particles in a size in the micrometer range. The calcium carbonate content can range from 40% to 60%. Microscopically small pores form in the vicinity of the calcium carbonate particles. However, the particles can also consist of another, in particular inorganic, material. The SD value sd is preferably 2 to 10 cm.

The bottom layer 7, which when using the roof underlay U towards the building on which the roof underlay U is used as a cover, forms a storage layer. The storage layer 7 can consist of a spunbonded nonwoven or a staple fiber nonwoven. The fleece that forms the storage layer 7 can be strengthened by needling during manufacture. The storage layer 7 can consist of polypropylene or polyester. It can have a high tear strength, greater than 250 N/50 mm. In addition, the storage layer 7 can have a high water vapor absorption rate. The latter can be at least 300 g/m ² .

At the in the figure 3 illustrated embodiment, the roof underlayment U has the same layer structure as previously based on the figure 2 described embodiment, which is why reference is made to the above statements. In this exemplary embodiment, however, the inner layer 7 can also be designed differently, for example not hydrophilic.

The roof underlay U has two longitudinal edges U' and U" pointing away from each other. The layers 1 to 5 extend from the first longitudinal edge U' to the second longitudinal edge U" and over the entire length of the roof underlay. The lowermost layer 7, which can preferably be a storage layer, has a smaller width than the roof underlay U. The edges 7', 7" are spaced less apart than the edges 5' and 5" of the uppermost lying layer 7 extending layer 5, which is preferably the functional layer.

As a result, the layers 1 to 5 form an overhang 9 that protrudes beyond the two edges 7', 7" of the layer 7 located underneath. The distance between an edge 5', 5" of the functional layer 5 and an edge between the respective The edge 7', 7" of the layer 7 lying at the bottom can be 5 mm to 150 mm.

This configuration is of particular advantage when the layer lying at the bottom is a water-absorbing layer which is fundamentally capable of transporting liquid water also by diffusion in the lateral direction. If two adjacent roofing underlays are connected to one another in an overlapping manner, at least in the edge area the overhang 9 rests on a water-repellent top layer 1 of the adjacent roofing underlay U, so that a non-water-transporting layer, namely the functional layer 5, is on a likewise non-water-transporting layer 1 rests.

The two overlapping roof underlays can be fitted with one in the figure 2 Adhesive strips, not shown, are connected to one another.

The Figures 4 and 5 show a third embodiment. The layer structure of this exemplary embodiment can correspond to the layer structure of the first exemplary embodiment or the second exemplary embodiment. With regard to the cross section of the layer structure, the third exemplary embodiment corresponds to the second exemplary embodiment.

At the in the Figures 4 and 5 illustrated embodiment, a first adhesive strip 10 is applied to the underside. It is a self-adhesive strip that has an adhesive property on both of its broad sides. The width b' of the first adhesive strip 10 is preferably 20 mm to 80 mm. According to a preferred embodiment, the first adhesive strip 10 is applied both over an edge section of the underlying layer 7, preferably storage layer 7, and over a section of the functional layer 5 adjoining it. The first adhesive strip 10 thus overlaps the edge 7' of the storage layer 7. It can seal the edge 7' of the storage layer 7.

A second adhesive strip 11 with a width b of preferably 20 mm to 80 mm is applied to the upper side. This is also a self-adhesive strip that has an adhesive property on both of its broad sides. While the first adhesive strip is arranged in the area of the first edge U', the second adhesive strip is arranged in the area of the edge U" opposite the first edge U'. Like the first adhesive strip, it runs parallel to the respective longitudinal edge U', U" of the roof underlay u

The figure 5 shows an example of an overlapping area of two roofing underlays U laid next to one another. The first adhesive strip 10 is glued to the second adhesive strip 11 of the adjacent roofing underlay U. It can be seen that the first adhesive strip 10, which is preferably water-impermeable, performs a sealing function with respect to the narrow edge 7' of the layer 7 lying at the bottom. The latter is in particular a consequence of the fact that the first adhesive strip 10 rests partly on the storage layer 7 and partly on a higher layer, in particular the next higher layer 5 .

When the internal humidity is moderate or low, the roofing underlay of the present invention has basically the same function as a prior art roofing underlay. If the indoor air has a different humidity than the outdoor air, water vapor can diffuse through the roof underlay from the side where the air humidity is higher to the side where the air humidity is lower. This can be done both from the inside out and from the outside in. However, the underlay differs from the prior art in that at a very high internal humidity with a low temperature of the inner surface of the underlay in the layer 7 at the bottom, the humidity can condense into liquid water that is stored in the layer 7 at the bottom. If the temperature subsequently rises or the relative humidity drops on the inside (but also on the outside), the liquid water can on the one hand evaporate to the inside. However, the vapor that forms when the water stored in the storage layer 7 evaporates can also diffuse through the functional layer and the other layers and evaporate to the outside.

The accumulation of liquid water on the inside of the roof underlay U can lead to a temporary blockage or reduced water vapor transportability. However, this potential disadvantage is overcompensated for by the storage capacity of the storage layer 7 .

The above statements serve to explain the inventions covered by the application as a whole, which also independently develop the state of the art at least through the following combinations of features, whereby two, several or all of these combinations of features can also be combined, namely:

An underlayment characterized in that the inner layer 7 is a water-absorbing storage layer 7 .

An underlay which is characterized in that the storage layer 7 is a spunbonded nonwoven or a staple fiber nonwoven.

An underlay characterized in that the storage layer 7 is made of polypropylene or polyester.

An underlay which is characterized in that the storage layer 7 is designed to store at least 300 g/m ² of water.

An underlay which is characterized in that the storage layer 7 has a tear strength of more than 250 N/50 mm.

An underlay which is characterized in that at least one edge 7' of the hydrophilic inner layer (storage layer 7) is spaced apart from the edge 5' of an overlying, in particular hydrophobic layer 5 by a distance a, a'.

An underlayment which is characterized in that a first adhesive strip 10 is arranged along a first edge U' of the underlayment U, at least in the area between the edge 7' of the inner layer 7 and the edge 5' of the layer 5 above it.

An underlayment, which is characterized in that along a second edge U" of the underlayment U opposite the first edge 7', a second adhesive strip 11 is arranged on the cover layer 1, which is able to form an adhesive connection with the first adhesive strip 10.

An underlay which is characterized in that the width b, b' of the first and/or second adhesive strip 10, 11 is between 200 mm and 800 mm.

An underlay which is characterized in that the cover layer 1 is a spunbonded nonwoven and/or consists of polypropylene.

An underlay which is characterized in that between the cover layer 1 and the storage layer 3 there is a functional layer 5, in particular a microporous film, which consists in particular of polypropylene or another polyolefin.

An underlay membrane, which is characterized in that an intermediate layer 3, in particular a meltblown fleece, is arranged between the cover layer 1 and the functional layer 5, which consists in particular of polypropylene or another polyolefin.

All disclosed features are essential to the invention (by themselves, but also in combination with one another). The disclosure of the application also includes the disclosure content of the associated/attached priority documents (copy of the previous application) in full, also for the purpose of including features of these documents in claims of the present application. The subclaims, even without the features of a referenced claim, characterize with their features independent inventive developments of the prior art, in particular for making divisional applications on the basis of these claims. The invention specified in each claim can additionally have one or more of the features specified in the above description, in particular with reference numbers and/or specified in the list of reference numbers. The invention also relates to designs in which some of the features mentioned in the above description are not implemented, in particular if they are clearly superfluous for the respective application or can be replaced by other technically equivalent means.

List of References

1 top layer u underlay 2 adhesive layer U' edge of the underlay 3 interlayer, interlayer U" edge of the underlay 4 adhesive layer 5 functional layer a Distance 5' edge of the functional layer a' Distance 5" edge of the functional layer b Width 6 adhesive layer b' Width 7 storage layer sd SD value 7' edge of the storage layer 7" edge of the storage layer 8th Substructure, roof, battens 9 Got over 10 first adhesive strip 11 second adhesive strip

Claims (14)

An underlay membrane (U) which is permeable to water vapor but impermeable to liquid water and has a covering layer (1) pointing outwards when laid on a roof or on a wall and an inner layer (7) pointing inwards, characterized in that at least one edge (7 ') the inner layer (7) is spaced in the extension direction of the underlayment from the edge (5') of an overlying layer (5) by a distance (a, a'), wherein along a first edge (U') of the underlayment (U) , a first adhesive strip (10) is arranged at least in the region between the edge (7') of the inner layer (7) and the edge (5') of the overlying layer (5). Underlay according to Claim 1, characterized in that a second adhesive strip (11) is arranged on the cover layer (1) along a second edge (U") of the underlay (U) opposite the first edge (7') and is capable of to enter into an adhesive connection with the first adhesive strip (10). Underlay according to Claim 1 or 2, characterized in that the width (b, b') of the first adhesive strip (10) is between 20 mm and 80 mm. Underlay according to Claim 2 or 3, characterized in that the width (b, b') of the second adhesive strip (11) is between 20 mm and 80 mm. Underlining according to one of the preceding claims, characterized in that the inner layer (7) is a water-absorbing storage layer (7). Underlining according to Claim 5, characterized in that the storage layer (7) is a spunbonded nonwoven or a staple fiber nonwoven. Underlay according to Claim 5 or 6, characterized in that the storage layer (7) consists of polypropylene or polyester. Underlining according to one of Claims 5 to 7, characterized in that the storage layer (7) is designed to store at least 300 g/m ² of water. Underlay according to one of claims 5 to 8, characterized in that the storage layer (7) has a tear strength of more than 250 N/50 mm. Underlay according to one of the preceding claims, characterized in that the inner layer (7) has a hydrophilic finish and the overlying layer (5) is hydrophobic. Underlining according to one of the preceding claims, characterized in that the cover layer (1) is a spunbonded nonwoven and/or consists of polypropylene. Underlay according to one of the preceding claims, characterized in that a functional layer (5), in particular a microporous film, which can consist of polyolefin and in particular of polypropylene, is arranged between the cover layer (1) and storage layer (7). Underlining according to one of the preceding claims, characterized in that between the cover layer (1) and the functional layer (5) an intermediate layer (3), in particular a meltblown fleece, is arranged, which consists in particular of polyolefin. Underlayment, characterized by one or more of the characterizing features of one of the preceding claims.

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