EP3879062A1 - Seal strip and method of manufacturing the same - Google Patents

Abstract

A sealing tape (1) is provided for sealing an intermediate space between a first component and a second component, in particular for windows or doors, with a cross-section that is essentially constant along a profile sheet (A). The sealing tape (1) has a functional area (2) formed from a first EPDM sponge rubber and an insulating area (3) formed from a second EPDM sponge rubber in a sectional plane lying transversely to the profiled sheet (A). The first EPDM foam rubber and the second EPDM foam rubber have different properties.

Description

The present invention relates to a sealing tape and a method for its production.

In the future, legal requirements may change in such a way that new buildings as passive houses and almost zero-energy houses will become the EU-wide standard. In achieving this goal, the building envelope plays a central role in the construction sector because it has a decisive influence on the energy balance and living comfort of a building. In particular, a seal for a window system has an immense influence on the overall assessment of the building envelope, despite the small area of such a seal. Various calculation models and U-value calculations have shown that the sealing properties of such a seal are essential for the entire building envelope. For example, when using highly insulating sealing materials, the U-value of the building envelope can be improved ^{by approx. 0.1 W / m 2 K.} Seals thus offer a very high potential for savings.

It is an object of the present invention to provide a sealing tape which has improved thermal insulation properties and at the same time has the known quality of EPDM seals (ethylene-propylene-diene rubber).

This object is achieved with a sealing tape according to claim 1 and a manufacturing method according to claim 11. Further advantages and features of the present invention emerge from the dependent claims. According to the invention, a sealing tape is provided for sealing a gap between a first component and a second component, in particular for windows or doors, with a cross-section that is essentially constant along a profile sheet or profile direction (A), the sealing tape in a sectional plane lying transversely to the profile sheet has a functional area formed from a first EPDM sponge rubber and an insulating area formed from a second EPDM sponge rubber (which can also be referred to as an insulation area), the first EPDM sponge rubber and the second EPDM sponge rubber having different properties. The sealing tape can be a strand-like body, which has its greatest extent along or parallel to the profile web. Along this extension or profile track, the sealing tape can preferably have a constant cross section or a constant cross sectional distribution in the functional area and in the insulating area. The phrase “essentially constant cross-section” includes smaller local deviations, such as notches or incisions, which can be made on the sealing tape at periodic intervals along the profile sheet. These can serve to improve the ability of the sealing tape to be laid in corners. The first component can be, for example, a window sash, whereas the second component can be a frame, in particular a frame or window frame, in which the window sash is held. Furthermore, the first component can be a door leaf and the second component can be a door frame. In addition, the first component can be a window sash and the second component can be a pane of glass held by the window sash. The sealing tape can cause damping and / or insulation by sealing the gap. Insulation can prevent or limit the spread of energy (ie heat or sound). Thus, an insulating effect can be achieved. In contrast, attenuation can be a conversion of kinetic energy into another, no longer relevant form of energy (ie energy dissipation can be achieved). For example, if the sound is insulated, the transmission of sound through reflection can be prevented. If the sound is attenuated, however, the sound energy can be converted into heat. The following is not expressly A distinction is made between insulation and damping, as both effects can be brought about by the same characteristics. Therefore, in the following, both terms are to be regarded as synonymous with one another. EPDM (written out ethylene-propylene-diene; M group) comprises terpolymers of ethylene, propylene and an unspecified diene. EPDM is one of the synthetic rubbers with a saturated main chain (according to DIN ISO 1629: M group). EPDM rubbers can have double bonds in the side chains and can therefore be vulcanized with sulfur. The use of EPDM is advantageous because EPDM has high weather and ozone resistance as well as high thermal resistance. It also has an advantageous chemical resistance to polar media (such as water or alcohol). In addition, EPDM only has a minor impact on the environment during production, processing and use, which is why it also meets the latest environmental standards. Furthermore, EPDM is characterized by its favorable processability and low material costs. Furthermore, sufficient permanent elasticity of EPDM should be mentioned as an advantageous property for a sealing tape in the context of the present invention. According to the invention, the EPDM is in the form of foam rubber. The foam rubber can be a largely closed-cell and elastic foam and belong to the pore rubbers. The foam rubber can be made from EPDM with the addition of propellants. Foam rubber can, for example, be extruded EPDM. The manufacturing process of the first sponge rubber for the functional area can differ from the manufacturing process of the second sponge rubber for the insulating area, so that, for example, a sponge rubber with a larger pore space is provided in the insulating area. In general, foam rubber is characterized by its advantageous thermal insulation properties. It is particularly advantageous that the entire functional area and the insulating area are made exclusively from foam rubber. The insulating area can be arranged in the intermediate space in such a way that it faces an outer side (ie, for example, a side exposed to the environment) of the first and the second component. The insulating area can mainly have insulating properties. In contrast, the functional area can face an inner side of the first and the second component and mainly mechanical properties such as fixing the sealing tape in the interspace and / or blocking a passage through the interspace. Nevertheless, the functional area can also have insulating properties. The different properties of the first EPDM foam rubber and the second EPDM foam rubber can be, for example, different density, elongation, tensile strength, elasticity, thermal conductivity, hardness, compression set at 100 ° C, compression set at -25 ° C, tensile strength and / or elongation. In particular, the density of the functional area can be higher than that of the insulating area by a factor in the range from 2 to 5, in particular in a range from 3 to 4.5. In particular, the elongation, tensile strength and elasticity of the second EPDM foam rubber can be negligible. In contrast, with the first EPDM foam rubber, the properties mentioned should reach a certain minimum value. The functional area can thus advantageously fulfill its main function, namely to hold the sealing tape in a desired position. Whereas the insulating area can advantageously fulfill its main function, namely to provide an insulating or insulating effect. In particular, the first foam rubber can have an elongation of greater than 100%. In contrast, the second foam rubber can have an elongation in a range from 0 to 200%. The elongation can be a relative change in length (ie an elongation or a shortening) of a body under load relative to a state without load. The first foam rubber and the second foam rubber can be connected to one another during a manufacturing process, for example. For example, the sealing tape can be produced by a coextrusion process. The first foam rubber and the second foam rubber can be brought together before leaving a profile nozzle which defines the desired cross section of the sealing tape. The profile nozzle can then define the shape of the functional area and the insulating area. According to the invention, it is therefore possible to provide a sealing tape that is formed from two different foam rubbers, so that the functional area has special properties and thus can provide functions such as fixing the sealing tape and / or an essentially airtight closure of the space, whereas the insulating area Has properties and thus Can provide functions such as damping and insulation. As a result, the sealing tape according to the invention can be provided which realizes the two contradicting properties, mechanical strength and durability, as well as improved insulation properties due to less strong material, in one sealing tape. Furthermore, due to the focus on its special properties, the insulation area can be made simpler and thus more cost-effective.

The functional area can preferably have a fastening section with which the sealing tape can be fixed to the first component or the second component. The fastening section can be designed to be brought into engagement with a complementary element formed on the first or the second component, wherein the fastening section can preferably be held in the complementary element in a form-fitting and / or force-fitting manner, in particular in a slot or a joint . Furthermore, the fastening section can be designed in the shape of a barb, so that it ensures a secure and permanent hold on the complementary element of the first or the second component. Furthermore, the functional area can have a support section which is supported on the first or the second component. The support section is preferably supported on the same component on which the fastening section is also fixed. The support section and the fastening section can expediently be arranged in such a way that the functional area is fixed to the first or the second component in a tensioned manner. In other words, the fastening section can define the functional area like a barb, whereas the support section presses against the first or the second component. The compressive force required for this can be brought about by the geometric shape of the support section and / or by material properties of the support section. A secure definition of the functional area and thus of the entire sealing tape can thus be achieved without the sealing tape wobbling or being able to slip. Furthermore, tolerances in the manufacturing process of the functional area can thus be compensated for and a secure hold of the sealing tape can nevertheless be achieved. In addition, it can be ensured that the sealing tape is in close contact with the first or the second Component is so that thermal bridges can be reliably interrupted and thus the insulation performance is ensured. Additionally or alternatively, a support section can be formed on the insulating area from the first foam rubber or the second foam rubber.

The functional area and the insulating area can be connected to one another, it being possible for a connecting line to be formed between the functional area and the insulating area. The connection can be materially bonded, for example in that the sealing tape is coextruded. The connecting line can have a force transmission section in which the connecting line extends essentially in a straight line. The section of the connecting line via which force is transmitted from the fastening section into the insulating area indirectly via or through the functional area can preferably be regarded as the force transmission section. The straight extension of the connecting line in the force transmission section has the advantage that stress peaks in the material can be avoided both in the functional area and in the insulating area and in particular in the contact area of the two areas. In the present case, the term essentially straight means that the connecting line in the force transmission section, in particular at its distal ends, can have small curves, in particular in order to achieve particularly low-stress transitions to the adjacent areas of the connecting line. In a preferred embodiment, the fastening section is arrow-shaped, the arrow-shaped geometry of the fastening section engaging a corresponding undercut on a frame (as an example of the first or second component) and being able to form a form-fitting and / or force-fitting engagement. The fastening section can be designed symmetrically to a line of symmetry. The line of symmetry can advantageously divide the functional area into two halves of equal size. In this way it can be ensured that the force transmitted by the fastening section is transmitted into the functional area in equal parts on the right and left side of the fastening section.

The functional area and / or the insulating area can have a projection, in particular a lip, which is designed to come into contact with the first or the second component. The projection can serve to establish a connection between the sealing tape and the first component or the second component, in particular in order to avoid or at least reduce the passage of gas (in particular air). In at least one position of the first and the second component in relation to one another, the projection can cause the gap to be mechanically blocked. In other words, the sealing tape can produce a connection between the first component and the second component that traverses the intermediate space. In other words, the first or the second component can be in contact with the fastening section, whereas the other of the first or second component is in contact at least with the projection. Thus, thermal bridges between the first and the second component can be reliably interrupted by the sealing tape and an improved insulating effect can be provided. Furthermore, the projection can be designed in such a way that it comes to bear against the first or the second component in a pretensioned manner. The preload can be brought about by the projection being inclined or bent in one direction in such a way that the first or the second component at least partially displaces the projection relative to the functional area in an assembled state of the sealing tape, compared with a non-assembled state of the sealing tape. Furthermore, the projection can have an elastic restoring force, so that the projection can apply a restoring force in the event of a displacement, which counteracts the direction of displacement. The elastic restoring force can be brought about by the material properties of the respective foam rubber and / or by a geometric shape of the projection. As a result, reliable sealing of the intermediate space can be achieved, since reliable contact of the projection on the first component or the second component is always ensured. In one embodiment, the projection is provided on the functional area. In a further embodiment, the projection is provided on the insulating area. It is also conceivable that a projection is provided on the functional area and the insulating area. The projection can protrude from the functional area and / or the insulating area into the space. Furthermore, the The insulation area and / or the functional area have an abutment section. The projection can be part of the contact section. The contact section can be designed to be wavy. The contact section can preferably be designed to come to rest on the first or second component, in particular on a pane. In this case, the contact section can reliably contact a surface that is not perfectly flat, in that the wavy contact section adapts to the shape of the surface. Furthermore, the contact section can have an essentially sinusoidal geometry. A wave crest of the undulating contact section particularly preferably has a smaller extension than the projection or projections. In this way, it can be ensured that the protrusion can always shield the contact section from external influences due to its greater extension in the direction of the first or second component and thus ensure particularly flawless contact between the contact section and the first or second component. In this way, it can in particular be prevented that grains of dust or liquids get into the area between the contact section and the first or second component.

The first EPDM foam rubber can have a density in a range from 0.1 to 2.0 g / cm ³ , in particular from 0.4 to 1.5 g / cm ³ . This density range has proven to be advantageous, since a sufficiently high resistance to physical and chemical influences, such as shocks, vibrations and temperature differences, can be achieved and a basic insulation function can be ensured at the same time. This is particularly advantageous because the functional area formed from the first foam rubber can be exposed to higher mechanical loads compared to the insulating area. Nonetheless, the functional area can provide a certain sealing function through the choice of the density area, so that the sealing tape can overall provide an improved sealing effect.

The second EPDM foam rubber can have a density in a range from 0.05 to 1.0 g / cm ³ , in particular from 0.1 to 0.4 g / cm ³ . A very high insulation effect can be achieved in this area, so that the insulation area is responsible for a high level of insulation for the sealing tape. Other material properties, such as, for example, the mechanical load-bearing capacity, are negligible in the insulation area, since the functional area assumes these functions in the sealing tape according to the invention.

The functional area and / or the sealing area can define at least one cavity that extends in the profiled sheet. In other words, the functional area and / or the insulating area can surround at least one cavity in the cross section of the sealing tape or at least one cavity can be provided in the functional area and / or the insulating area. The cavity can be designed in such a way that the overall geometric stability of the sealing tape is increased. Furthermore, the cavity can improve the insulation properties. Thus, on the one hand, the stability and, on the other hand, the sealing property of the sealing tape can be improved by the cavity. In particular, the cavity can have an essentially rectangular shape in cross section. Furthermore, several cavities can also be provided, in particular five cavities can be provided. The functional area can expediently have two cavities, one of which is preferably arranged in the fastening section. The insulation area can have three cavities. In an alternative embodiment, five cavities can be provided in the insulating area.

The first EPDM foam rubber can have a hardness of greater than 40 Sh A and / or the second EPDM foam rubber can have a hardness of less than 40 Sh A. With this hardness, the functional area can provide its function (i.e. to hold the sealing tape and provide a seal between the first component and the second component) and at the same time be sufficiently resistant to wear. In contrast, it is sufficient for the insulation area that it has a lower hardness, since the main function of the insulation area is insulation, for which a hardness of> 40 Sh A is sufficient.

The first EPDM foam rubber can have a tensile strength of greater than 5 N / mm ² and / or the second EPDM foam rubber can have a tensile strength in a range from 0 to 5 N / mm ² . Thus, the mechanical strength of the Functional area and the insulation area be designed for the main function assigned in each case. Furthermore, the resilience of the first foam rubber can be approximately 1.5-3 times the resilience of the second foam rubber. The preferred ratio of the resilience ensures that the functional area, which has to absorb the higher, often fluctuating forces in use, has the same service life as the insulating area. Thus, the reliability of the sealing tape can be increased as a whole.

The first EPDM foam rubber can have a thermal conductivity in a range from 0.05 to 0.5 W / (mK), in particular from 0.08 to 0.35 W / (mK), and / or the second EPDM foam rubber can have a Thermal conductivity in a range from 0.01 to 1.0 W / (mK), in particular from 0.01 to 0.08 W / (mK). The thermal conductivity, also called the coefficient of thermal conductivity, can be a material property that determines the heat flow through the first foam rubber and the second foam rubber on the basis of thermal conduction. The thermal conductivity shows how well a material conducts heat or how well it is suitable for thermal insulation. The lower the value of the thermal conductivity, the better the thermal insulation.

According to another aspect of the present invention, there is provided a method of making the above sealing tape. The sealing tape according to the invention can be formed by a coextrusion step, so that the first foam rubber and the second foam rubber are brought together to form the sealing tape. The first EPDM foam rubber and the second EPDM foam rubber can thus preferably be formed with one another. In this way, in particular, a cost saving can be achieved, since the production of a sealing tape by coextrusion is particularly rapid and a particularly firm connection between the first EPDM foam rubber and the second EPDM foam rubber can be produced in a simple manner. In addition, time can be saved in production, which in turn enables production costs to be saved. In particular, the constant formation of the functional area and the insulating area along the profile sheet favors the production of the sealing tape Coextrusion, since particularly simple geometries can be provided on both extrusion dies. A particularly high level of skill in connecting the functional area and the insulating area can be achieved by coextruding. The very good networking of the two foam rubbers in particular contributes to this.

Figur 1

ein Profil des Dichtungsbands gemäß einer Ausführungsform der vorliegenden Erfindung,

Figur 2

ein Profil des Dichtungsbands gemäß einer weiteren Ausführungsform der vorliegenden Erfindung,

Figur 3

ein Profil des Dichtungsbands gemäß einer weiteren Ausführungsform der vorliegenden Erfindung, und

Figur 4

eine schematische dreidimensionale Ansicht eines Dichtungsbands gemäß der Ausführungsform der vorliegenden Erfindung, wie es von einer Rolle abgewickelt wird.

Further advantages and features of the present invention emerge from the following description with reference to the attached figures of selected preferred exemplary embodiments. It goes without saying that individual features shown in only one of the figures can also be used in other embodiments in which these are not explicitly shown. Show it:

Figure 1

a profile of the sealing tape according to an embodiment of the present invention,

Figure 2

a profile of the sealing tape according to a further embodiment of the present invention,

Figure 3

a profile of the sealing tape according to a further embodiment of the present invention, and

Figure 4

Fig. 3 is a schematic three-dimensional view of a sealing tape according to the embodiment of the present invention as it is unwound from a roll.

In Figure 1 a profile of a sealing tape 1 according to the invention is shown. The sealing tape 1 extends along a profile sheet A (see Fig. 4 ). The profile corresponds to a cross section in a sectional plane which runs transversely to the profile sheet A of the sealing tape 1. The sealing tape 1 has a functional area 2 and an insulating area 3. In the functional area 3, a fastening section 4 is provided with which the sealing tape 1 can be fixed to, for example, an undercut of a window frame. Furthermore, the functional area has a projection which is designed as a lip 5 which, when a window sash that is held in the window frame, is closed, is in contact with the window sash. The functional area 4 thus establishes a connection between the window frame and the window sash and physically interrupts a thermal bridge between the window frame and the window sash. The functional area 2 is made of an EPDM material (ethylene-propylene-diene rubber), which is designed as a foam rubber (ie a driven EPDM). In the following, the material from which the functional area is formed is referred to as a first EPDM foam rubber. In the same way, the insulating area 3 is formed from an EPDM material, which is designed as a foam rubber (ie a driven EPDM). In the following, the material from which the insulation area is formed is referred to as a second EPDM foam rubber. The second foam rubber has a significantly lower density than the first foam rubber. More precisely, the first foam rubber has a density that is approximately a factor of 4 higher than the second foam rubber. Furthermore, the functional area has two cavities or recesses 6, which extend in the profile sheet A. A cavity 6 is arranged in the fastening section 4. In addition, the insulating area 3 has three further cavities 6, which also extend along the profile sheet A. Furthermore, the functional area 2 has a support section 7 which interacts with the fastening section 4 in such a way that, when the sealing tape 1 is attached to a component, the sealing tape is braced against the component in order to be securely held thereon. Furthermore, the sealing tape 1 has a hook section 8 in the profile, which is provided on the insulating area 3. With the hook section 8, the sealing tape 8 can additionally be secured against detachment on a component to which it is fixed. The hook section 8 cooperates with a further undercut on the respective component. More precisely, behind the hook section 8 engages a complementary section on the component. This prevents the insulating area 3 from being folded down or tipping away from the component on which the sealing tape 1 is attached.

In Figure 2 another embodiment of the present invention is shown. In the present embodiment, the functional area 2 is essentially limited to the fastening section 4. The remainder of the profile of the sealing tape 1 consists of the insulating area 3. In the present embodiment, the lip 5 is formed on the insulating area 3. Furthermore, the insulating area 3 has five cavities 6. Furthermore, the sealing tape 1 has a contact section 9 which is formed on the insulating region 3. The contact section 9 comes to rest on the first or second component. For example, the sealing tape 1 of the present embodiment is used as a glass gasket. The fastening section 4 is fixed to a frame of a glass pane and the insulating area 3 is pressed with its contact section 9 against the glass pane.

Figure 3 is a further embodiment of the present invention and corresponds essentially to the previous embodiment with the exception that the insulating area 3 has two symmetrical lips 5 which are provided on the contact section 9. The two lips protrude further from the insulating area 3 than the contact section 9. In the present embodiment, the functional area 2 essentially consists of the fastening section 4. Furthermore, the insulating area 3 has a cavity 6.

In Figure 4 Finally, a schematic three-dimensional view is shown, which shows the sealing tape 1 of the previous embodiment as it is being unwound from a roll. The profile sheet A, in which the sealing tape 1 extends, can be seen.

List of reference symbols

1

Sealing tape

2

Functional area

3rd

Insulation area

4th

Fastening section

5

Projection (lip)

6th

cavity

7th

Support section

8th

Hook section

9

Plant section

Claims (11)

Sealing tape (1) for sealing a gap between a first component and a second component, in particular for windows or doors,
with a cross-section that is essentially constant along a profile sheet (A),
wherein the sealing tape (1) has a functional area (2) formed from a first EPDM sponge rubber and an insulating area (3) formed from a second EPDM sponge rubber in a sectional plane lying transversely to the profile sheet (A),
wherein the first EPDM sponge rubber and the second EPDM sponge rubber have different properties. Sealing tape (1) according to claim 1, wherein the functional area (2) has a fastening section (4) with which the sealing tape (1) can be fixed to the first component or the second component. Sealing tape (1) according to one of the preceding claims, wherein the functional area (2) and the insulating area (3) are connected to one another, a connecting line preferably being formed between the functional area (2) and the insulating area (3). Sealing tape (1) according to one of the preceding claims, wherein the functional area (2) and / or the insulating area (3) has / have a projection (5), in particular a lip, which is designed to be with the first or the second component to get in touch. Sealing tape (1) according to one of the preceding claims, wherein the first EPDM foam rubber has a density in a range from 0.1 to 2.0 g / cm ³ , in particular from 0.4 to 1.5 g / cm ³ . Sealing tape (1) according to one of the preceding claims, wherein the second EPDM foam rubber has a density in a range from 0.05 to 1.0 g / cm ³ , in particular from 0.1 to 0.4 g / cm ³ . Sealing tape (1) according to one of the preceding claims, wherein the functional area (2) and / or the sealing area (3) defines / define at least one cavity (6) which extends in the profile sheet (A). Sealing tape (1) according to one of the preceding claims, wherein the first EPDM foam rubber has a hardness of greater than 40 Sh A and / or the second EPDM foam rubber has a hardness of less than 40 Sh A. Sealing tape (1) according to one of the preceding claims, wherein the first EPDM foam rubber has a tensile strength of greater than 5 N / mm ² and / or the second EPDM foam rubber has a tensile strength in a range from 0 to 5 N / mm ² . Sealing tape (1) according to one of the preceding claims, wherein the first EPDM foam rubber has a thermal conductivity in a range from 0.05 to 0.5 W / (mK), in particular from 0.08 to 0.35 W / (mK), and / or the second EPDM foam rubber has a thermal conductivity in a range from 0.01 to 1.0 W / (mK), in particular from 0.01 to 0.08 W / (mK). Method for producing a sealing tape (1) according to one of Claims 1 to 10.

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