DE102009026864B4 - Sealing element with thermoexpandable substance and thermally insulated system with such sealing element - Google Patents

Abstract

Sealing element (10), in particular joint sealing strip, for the sealing of an edge region (42) of a component against an adjacent connection region (44) of a building, vehicle or the like, wherein the sealing element (10) is formed of a flexible polyurethane foam and at least one thermoexpandable Contains substance, wherein the at least one thermoexpandable substance is homogeneously distributed in the sealing element (10), whereby at such changing temperature conditions that the cold side of the sealing element (10) once on the inside and then again on the outside of the sealing element (10) , it is always ensured that a warm side of the sealing element (10) seals better than a cold side of the sealing element (10), wherein the thermoexpandable substance is formed from nanoparticles, wherein the thermoexpandable substance comprises particles having a particle size of 1-100 nm exhibit.

Description

The present invention relates to a sealing element, in particular a joint sealing strip, especially a precompressed or uncompressed joint sealing strip with or without pressure-sensitive adhesive, for sealing a peripheral region of a component against an adjacent connection region of a building, vehicle or the like, and a thermally insulated system comprising such a sealing element includes.

Recently, more and more emphasis is placed on the fact that buildings and individual rooms as well as vehicles and the like are isolated as well as possible. Especially in buildings connecting joints of windows and doors are particularly good, i. E. sealed according to the recommendations of the Energy Saving Ordinance (EnEV). For this purpose, it is necessary that, as a rule, the seal on the inside facing an interior is more airtight and vapor diffusion-tight than on the outside facing an exterior. The reason for this is that from the rather warm and possibly damp interior, especially in the colder season, as little air as possible and, if possible, no steam should penetrate into the seal, because in the seal the air containing the vapor would cool and liquid would condense out. This could lead to an accumulation of moisture and at worst to the destruction of the surrounding areas of the seal, for example by mold. In contrast, the outer part of the seal should be more permeable to air, and especially to steam, in order to allow any penetrated moisture to be better diffused outwards.

In order to achieve these functions of a seal, conventionally a joint seal made of a foam system such as a two-component PU foam is used, on which on the side facing the outside of a relatively permeable to the diffusion of vapor film and on the inside facing side is mounted for the diffusion of steam relatively impermeable film. When installing such a joint system, it is disadvantageous that must be handled with three different materials, which not only increases the time for installation, but also increases the likelihood of errors in the installation of such a seal.

The aforementioned recommendation according to the so-called RAL principle, according to which the seal should be stronger inside than outside, is hygrothermally correct in winter so that the warm moist air of the interior can diffuse diffused into the insulation through the joint. If this happens, the moisture is effectively removed to the outside before it can condense. In the summer, however, where the outside air i.d.R. warmer and more humid than the indoor air, it would be hygrothermally useful to provide the air or vapor barrier outside.

The DE 10 2006 043 050 A1 relates to a foam-sealing strip, which is impregnated for delayed recovery, wherein the foam-sealing strip has two opposite, respectively in the installed state of the inside and the outside of the window facing narrow sides and to rest against the window side or reveal suitable broadsides.

The DE 20 2005 000 873 U1 relates to a sealing tape for sealing a joint between a frame used in a soffit of a building and the soffit, wherein the sealing tape is formed of a composite comprising at least two layers and a first layer of the composite of a plastic nonwoven based on continuous fibers and / or meltblown microfibers and a second layer of the composite is formed from a film.

The EP 1 705 232 A1 discloses a sealing element which consists of a base material made of permanently elastic foam and has at least partially small plastic balls, which consist of a polymer shell with gas contained therein and are expanded due to heating, so that the sealing element has a reduced air permeability and an increased watertightness.

The DE 38 08 275 A1 discloses fire protection elements characterized by comprising foam bodies which are resilient when damp and which provide a liquid, non-fouling impregnation, one or both of which solidify upon drying upon installation and the fire protection elements are protected against moisture loss prior to installation ,

The EP 1 600 571 B1 discloses a sealing member made of soft, flexible foam. According to the invention, due to a homogeneous impregnation of the entire sealing element with an impregnate, the provision of the sealing element is substantially homogeneous and delayed over the entire length and width of the sealing element.

The DE 31 00 746 A1 discloses a sealant made of polyurethane rubber, which crosslinks by means of humidity and contains the pressure-elastic hollow microspheres and thereby reversible in compression.

The present invention has for its object to provide a sealing element for the sealing of an edge region of a component against an adjacent terminal region of a building, vehicle or the like, and a thermally insulated system comprising such a sealing element, whereby the described disadvantages can be avoided denser side of the sealing element is always located on the "right" side and a faster, more efficient and less error-prone installation can be realized.

This object is achieved with a sealing element according to claim 1 or a thermally insulated system according to claim 21. Advantageous developments of the invention are the subject of the dependent claims.

The sealing element according to the invention contains a thermoexpandable substance or even several different thermoexpandable substances. "Thermoexpandable substance" means that this substance contains particles that expand when exposed to temperature, ie take up more space. In the case in which a spatial expansion of the sealing element is not possible, this leads to a greater compression of the material in which the particles are located. It may be advantageous if several different thermo-expandable substances are used in order to combine their respective advantages or properties with each other. The use of the thermo-expandable substance (s) in a sealing element has the advantage that the sealing element seals more tightly at the side which is warmer than at the point which is colder. The use of thermoexpandable substances is particularly advantageous because even with such strongly changing temperature conditions that the cold side of the sealing element is once on the inside and then again on the outside of the sealing element, it is always ensured that the warm side of the sealing element better seals than their cold side.

According to the invention, the thermoexpandable substance is homogeneously distributed in the sealing element, so that this can be made simpler and easier to install, since - assuming a corresponding geometric design of the sealing element - then there is no risk of confusion between inside and outside during installation.

In practice, nanoparticles, hollow microspheres or microwaxes have proven to be advantageous thermoexpandable substances.

The thermoexpandable substance comprises particles which have a particle size of 1 to 100 nm. The particle size is more preferably 2 to 50 nm, with a value of about 20 nm being particularly preferred. In addition, particle sizes of 1 to 100 microns, for micro-axis preferably 50 microns, can be used.

The sealing element according to the invention advantageously has a density of between 20 and 300 kg / m ³ , wherein a density of 40 to 200 kg / m ^{3 is} more preferred. Particularly preferred is a density of about 70 kg / m ³ .

According to an advantageous embodiment, the sealing element according to the invention has a cell structure with at least 20 cells per cm length of the sealing element, preferably at least 25 cells per cm. These values apply both to the polyurethane foam used to produce the sealing element and to the finished sealing element.

The sealing element according to the invention preferably contains a soft polyurethane foam with a density between 10 and 60 kg / m ³ , with a value between 18 and 50 kg / m ³ and in particular a value of about 28 kg / m ^{3 is} preferred.

It is advantageous in this case to design the air permeability of the soft polyurethane foam so that it does not exceed a value of 150 l / m ² s, preferably even not exceed a value of 100 l / m ² s. The air permeability is measured according to DIN EN ISO 9237 (10 mm, 50 Pa). The term "10 mm" refers to a sealing element with a thickness of 10 mm during the measurement.

The sealing element according to the invention extends between a first section and a second section in a width direction and, transversely to the width direction, has in each case one installation edge facing the edge region and the connection region in a thickness direction. According to an advantageous embodiment, the two mounting edges are at least substantially plane-parallel. "At least substantially plane-parallel" here means that it does not depend on the exact parallelism of the two mounting edges, but that they may well have customary deviations thereof, which do not affect the functionality of the sealing element. A sealing element with such a configuration can be installed in a simple manner without bias.

In contrast, according to an alternative advantageous embodiment, the sealing element is profiled so that it has a greater thickness in the region of the first portion than in the region of the second portion. Since the sealing element in the region of the first portion is thicker than in the region of the second portion, it is in the installation between the edge region of a component, such as for example, a frame of a window or door, and the terminal portion of a building such as the masonry, a vehicle, or the like at the location where it is thicker, more compressed than at the location having a smaller thickness. The higher degree of compression in the first section necessarily results in a higher air barrier and vapor diffusion than in the less compressed section in the second section. Thus, in this embodiment, the different tightness of the sealing element achieved by the use of the thermoexpandable substance on the different sides can be enhanced. In the case of the use of this embodiment of the sealing element according to the invention in a normal building is thus to ensure that preferably the first portion of the interior of a room or the building side facing and the second section corresponds to the outside of the building side facing. Should the sealing element according to the invention be used for example for sealing a cooling space, the first portion of the sealing element to the outside, ie the warmer side, to align and the second section towards the inside, so the cooled side directed.

Preferably, the sealing element according to the invention is profiled so that it has a greater thickness in the region of the first portion than in the region of the second portion in the absence of external action, and is compressible or compressible such that its thickness from the first portion to the second portion is substantially the same when installed between the edge region and the connection region. "In the absence of external action" here and below means that the sealing element is not bent and in particular is not compressed, that is, the sealing element is in the relaxed state and not in the installed state. In the case of details of the thickness of the sealing element or joint sealing strip, it is assumed below without any special mention that these details refer to the state in the absence of external influence.

Further preferably, in the sealing element according to the invention, the first portion and the second portion are respectively at the boundaries in the width direction. In other words, the first portion and the second portion form the boundaries of the sealing member in the width direction. In particular, the sealing element at the edge, which forms the first portion, the thickest and at the edge, which forms the second portion, the thinnest.

It is preferred that in the sealing element according to the invention, the thickness increases monotonically from the second section to the first section. This means that the thickness there either increases or at least remains the same, but in no way decreases.

Preferably, the thickness of the sealing element according to the invention between the mounting edges from the second portion to the first portion toward - at least partially - in the absence of external influence linearly. In the sections with linear or uniform increase in thickness changes after installation of the sealing element according to the density and thus the insulating ability and the vapor permeability of the sealing element according to uniform.

By such a uniform change in thickness, the sealing element according to the invention can be compressed relatively easily.

Furthermore, it is preferable for a third section of the sealing element with a first value of the thickness to be provided in the region of the second section, and a fourth section having a second value of the thickness being larger than the first being provided in the region of the first section Value of the thickness is, wherein the thickness increases monotonically from the third section to the fourth section. In other words, the third portion has a constant thickness, and the fourth portion also has a constant thickness larger than the thickness in the third portion, and the thickness of the sealing member gradually increases from the third portion to the fourth portion. In this way, it is possible to define regions of precisely defined density and thus vapor permeability, in particular in the case of the installation edges of the sealing element, and in the section between them the thickness and thus the vapor diffusion capacity increases monotonically.

Alternatively, an advantageous development of the invention is that in the region of the second portion, a third portion of the sealing element is provided with a first value of the thickness, and that in the region of the first portion, a fourth portion is provided with a second value of the thickness, the larger is the first value of the thickness, the third portion and the fourth portion being immediately adjacent to one another to form a step. This two-section configuration, each of constant thickness, has the advantage that the two corresponding areas each have well-defined thermal and vapor diffusion properties.

A further advantageous development of the invention consists in that the thickness of the sealing element from the second section to the first section gradually, for example linearly, increases up to a maximum and then decreases again. It may be favorable if in this case the increase in the thickness of the sealing element begins only in the region of the middle between the first section and the second section. It is advantageous here that the area of the sealing element which has to be compressed remains relatively small.

It may be advantageous that the thickness of the sealing element decreases from the second section to the first section and then increases again, wherein the thickness of the sealing element at the second portion is smaller than at the first portion, whereby the sealing element according to the invention in the region of the second section open to the Vapor diffusion is considered in the area of the first section.

A greater variation of the insulating ability and the vapor diffusion barrier effect can be achieved if the thickness of the sealing element decreases from the second section to the first section, then increases again and finally decreases again, wherein the thickness of the sealing element is smaller at the second section than at the first section to ensure the highest vapor barrier effect in the area of the first section.

The sealing element may be lighter and more homogeneous to be compressed during installation, when the transitions between sections of different thickness are each rounded.

A further advantageous embodiment of the invention is to form the two mounting edges symmetrically with respect to an axis extending from the first section to the second section. In this case, there may be a simplification of the installation of the sealing element according to the invention, since it does not need to be differentiated, which section of the sealing element is to be installed facing the edge region or the connection region.

It may also be advantageous to design one of the two mounting edges profileless. This smooth mounting edge can then attach particularly easily to the edge region of the component or at the connection area. Alternatively, a further sealing element may be attached to the profiled-trained mounting edge, which is also provided with a profillos trained mounting edge, wherein the connection is made via the two profiled mounting edges. If the further sealing element is also profiled, for example, a mirror-symmetrical configuration of the composite - e.g. in the form of a wedge - are formed from the two sealing elements. In addition, it is possible to use as a further sealing element a completely profillos designed sealing element, so as to increase the total thickness that can take the sealing element. Further, it is possible to connect two differently profiled sealing elements, each with a profiled-trained mounting edge to these profile-less mounting edges, so as to obtain a correspondingly thick, both sides profiled sealing element. In this way, the sealing element can be adapted to a wide variety of installation configurations.

The sealing element according to the invention is preferably impregnated homogeneously with an impregnating agent to improve the sealing effect by immersion in the impregnating substance present in liquid form. This has the advantage that not only does a particular area of the sealing element need to be soaked, while the remaining part of the sealing element remains free of impregnating substance or is soaked only weakly, but that the impregnating process to achieve a homogeneous impregnation is substantially simplified. The impregnating agent is usually a polyacrylate or rubber dispersion with various fillers, flame retardants and water content. By subsequent drying, the water content disappears, leaving behind the impregnating mass which has settled around the foam structure. The drying takes place in such a way that the sealing element remains viscoelastic.

In one embodiment of the sealing element according to the invention as a joint sealing strip product properties such as watertightness of at least 600 Pa and a thermal insulation with a U value of about 0.7 W / m ² K are achieved, wherein such a joint sealing tape simultaneously open against vapor diffusion on the one hand and airtight as well as damp-braking on the other side. In the usual use of such a joint sealing tape in the construction sector is then usually the airtight section on the inside and the vapor diffusion opener section on the outside, ie towards the open, arranged. The sealing effect of such a jointing tape contributes to its installation during compression with appropriate compaction of the material of the joint sealing tape, while with differently shaped sealing elements with, for example, a sealing lip, the sealing effect by applying or pressing the sealing lip to the component to be sealed and possibly bending the sealing lip.

According to the invention, therefore, a sealing element, in particular a strand-shaped joint sealing strip, with a width adapted to the window frame for joints of about 2-40 mm, in particular 3-27 mm, realized. Depending on the dimension, it is possible to one or more of the sealing element or joint sealing strip according to the invention to apply further layers to profileless or profiled joint sealing strips.

The sealing element according to the invention can thus be handled much faster and independent of the weather, since the installation of the window can be done faster, because only a single material needs to be glued to a window frame without pretreatment of the substrate. The sealing element according to the invention fulfills its described function in any weather such as rain, fog, cold or heat. In contrast, two-component foams for thermal insulation are more difficult or impossible to process, depending on temperature and humidity.

The sealing element according to the invention is made of PU foam and is preferably delivered as compressed as a role to the customer, that the so-called delivery form despite being possibly different contours is plane-parallel. The possibly more compressed section is usually marked. The mark can u. a. in the inner core, on the outer roll surface or the roll side surface, for example, by color, imprint or colored foil tape can be realized.

Various embodiments are available with and without self-adhesive on the non-profiled side.

A thermally insulated system according to the invention comprises a structural element, such as a door, window or the like, with a peripheral area, such as a frame. Furthermore, the system according to the invention comprises a connection region, which is adjoined by the edge region and which forms a joint to be sealed with the latter as a rule. In a building, the connection area is, for example, the masonry, while the connection area in a vehicle is, for example, the body. Furthermore, the system according to the invention comprises a sealing element, such as, for example, a previously described joint sealing strip, for the sealing of the edge region against the adjacent connection region.

In the heat-insulated system according to the invention, the sealing element contains a thermo-expandable substance or even several different thermo-expandable substances. The provision of a plurality of different thermo-expandable substances can bring the advantage that their respective advantages or properties can be combined with each other.

The use of thermo-expandable substances in a sealing element of the thermally insulated system has the advantage that the sealing element seals more tightly on the side which is warmer than at the point which is colder. The use of thermoexpandable substances is particularly advantageous because even with strongly changing temperature conditions is always ensured that the better sealing side of the thermally insulated system is always located at the lower point. In other words, the warm side of the sealing element always seals better than its cold side.

In this case, the sealing element extends between a first portion and a second portion in a width direction and has transversely to the width direction in a thickness direction depending on the edge region and the connection region facing the mounting edge.

The two mounting edges may on the one hand be parallel to each other, on the other hand, the sealing element may alternatively be profiled so that it has a greater thickness in the region of the first portion than in the region of the second portion in the absence of external action, in particular pressure or stress. The sealing element is arranged and compressed in the heat-insulated system according to the invention between the edge region and the connection region such that its thickness is essentially the same from the first section to the second section. The increased compression in the first section of greater thickness results in a higher density of material of the sealing element at that location, resulting in enhanced impermeability to vapor diffusion. Accordingly, at the point where the sealing element is only slightly compressed due to the smaller width, the heat-insulated system according to the invention is more permeable to the diffusion of vapor. Thus, in this system, only a joint sealing strip of a single material needs to be used, which facilitates handling, especially during installation considerably.

Further advantages, features and special features of the invention will become apparent from the following description of advantageous embodiments of the invention not shown to scale seal element or thermally insulated system. Show it:

1 in cross-sectional view of an embodiment of a sealing element according to the invention with plane-parallel mounting edges at the same internal and external temperature,

2 in cross-sectional view of the embodiment of 1 at an internal temperature greater than the outside temperature,

3 in cross-sectional view of another embodiment in which the sealing element according to the invention is formed in two layers,

4 - 11 different profiles of further embodiments of the sealing element according to the invention in cross section and

12 a heat-insulated system according to the invention in cross section.

Hereinafter, for the description of embodiments of the invention for simplicity, it is assumed that the sealing element according to the invention 10 is designed as a joint sealing tape, the invention is of course not limited to this example.

1 shows a first embodiment of a joint sealing strip according to the invention 10 for sealing a joint, for example between a door and a masonry, to simplify the representation in the 1 - 11 not shown.

The joint sealing tape 10 extends from a first section 11 , which faces the inside of the building, to a second section 12 , which faces the outside of the building. In this case, the extension direction defines the first section 11 to the second section 12 the width direction. Transverse to this width direction is the joint sealing strip 10 by a - shown below - installation edge 19 and a - shown above - built-in edge 18 bounded, which is substantially parallel to the lower mounting edge 19 is. These two mounting edges 18 . 19 define the thickness of the joint sealing tape 10 and are facing the frame or masonry or vice versa.

The joint sealing tape 10 contains at least one thermoexpandable substance, which consists of particles 50 is formed. These particles are so-called nanoparticles. Furthermore, it is additionally possible to provide hollow microspheres or components of a microwax as further thermo-expandable substances. The particles 50 have a size of 1 to 100 nm, but a size of 2 to 50 nm and ideally a size of 20 nm is preferred. In addition, particles of 1 to 100 .mu.m, preferably of 50 microns (microwaxes) may be included. For producing a joint sealing strip according to the invention 10 is a soft foam made of PUR (polyurethane) soaked with a means that the particles 50 contains. The arrangement of the particles 50 as shown in 1 is only to be regarded as schematic. In other words, that means the particles 50 are not arranged one above the other, but relatively randomly distributed. This corresponds to a substantially homogeneous distribution of the particles in the joint sealing tape 10 , Starting from a flexible polyurethane foam having a bulk density between 10 and 60 kg / m ³ , preferably between 18 and 50 kg / m ³ and in particular about 28 kg / m ³ , is added by adding the impregnating agent with the particles 50 made of thermoexpandable substance a density between 20 and 300 kg / m ³ achieved. Preferably, the achievable density is between 40 and 200 kg / m ³ and in particular about 70 kg / m ³ . In this way, a sealing element is produced which has a cell structure in which there are at least 20 porous cells per cm of running length and preferably at least 25 such cells. The air permeability of the soft polyurethane foam as a starting point for the production of a sealing element or joint sealing tape according to the invention has a value of not more than 150 l / m ² s and preferably a value of not more than 100 l / m ² s, this value according to DIN EN ISO 9237 (10 mm, 50 Pa). In 1 the situation is shown in which the temperature t ₁ on the inside is equal to the temperature t ₂ on the outside.

In 2 the situation is shown schematically, in which the internal temperature t ₁ shown here on the left is greater than the outside temperature t ₂ shown here on the right. At these different temperatures, the thermo-expandable substances expand in the form of the particles 50 different degrees of strength: the particles 50 on the warm side at t ₁ stretch much more than the particles 50 on the cold side at the temperature t ₂ and thereby lace the pores not specifically shown in the joint sealing tape 10 strong. These pores may, for example, be closed or at least substantially closed pores. The smaller the pores due to the expansion or expansion of the particles 50 The more difficult it becomes for air or steam, the joint sealing strip according to the invention 10 to penetrate. This will achieve the situation that the joint sealing tape 10 on the warm side is denser than on the cold side. In other words, the joint sealing tape 10 on the cold side more open than on the warm side.

In 3 is a second embodiment of the sealing element according to the invention 10 shown at the lower edge of the mounting 19 another, here equal dimensioned illustrated second joint sealing strip 30 is included. In this way, a thicker joint sealing strip can be obtained by joining several thinner joint sealing strips. This connection can be done for example by simple gluing. As a result, the joint sealing tapes according to the invention need not be produced in different thicknesses or only in substantially less different thicknesses, and the required thicknesses can be achieved on site by joining suitable joint sealing tapes become. Thus, the jointing sealing strip according to the invention can be multi-layered, that is to say comprise two or more layers of strips.

4 shows a third embodiment of a joint sealing strip according to the invention 10 , Out 4 It can be seen that the thickness of the joint sealing tape 10 at a fourth section 14 which is in the area of the first section 11 (ie, here the inside) is greater than the thickness of a third section 13 that is in the area of the second section 12 (ie here the outside) is located. From the second section 12 or third section 13 to the first section 11 or fourth section 14 increases the thickness of the joint sealing strip smooth or linear, ie the mounting edge 18 forms a straight line in cross section. Also the mounting edge 19 forms a straight line in cross section, being substantially perpendicular to the first section 11 limiting surface and the second section bounding surface is. The recessed edge 18 However, it is against the first and second sections 11 respectively. 12 inclined or defining surfaces. Below the mounting edge 19 is in this embodiment and in the in the 5 to 11 embodiments shown another joint sealing strip 30 with cuboidal cross-section - ie with non-profiled, unspecified mounting edges - connected to achieve a greater total thickness of the joint sealing strip. The presence of this further joint sealing tape 30 However, is not essential to the present invention, but is only an advantageous development.

In the 5 to 11 unless otherwise stated, like reference numerals refer to like features and therefore need not be re-described in every case.

5 shows a fourth advantageous embodiment of the joint sealing strip according to the invention 10 , A fourth section 14 (shown here on the left) has a uniform or constant thickness. The thickness corresponds to the maximum distance between the two mounting edges 18 and 19 , A third section, shown here on the right 13 also has a constant thickness, but smaller than the thickness in the fourth section. From the third section, the thickness increases continuously or linearly up to the fourth section.

6 shows a further, fifth advantageous embodiment of the invention, a modification with respect to in 5 illustrated embodiment in that the transitions from the third section 13 and the fourth section 14 rounded to the area with a constant change in thickness. The rounding can take place, inter alia, in the form of a circular arc section.

7 shows a sixth advantageous embodiment of the invention. In this embodiment, have the third section 13 and the fourth section 14 each a constant thickness, the thickness of the fourth section 14 greater than the thickness of the third section 13 is. The two sections 13 and 14 form a stage 15 at the point where they adjoin one another.

At the in 8th illustrated seventh advantageous embodiment of the invention takes the thickness of the joint sealing tape 10 from the third section 13 after a rounding at the right edge continuously linear with a further rounding up to a maximum in the fourth section 14 to, then to the left edge again (rounded) to decrease to a thickness, as roughly the thickness at the right edge of the third section 13 equivalent. It should be noted that the fourth section 14 not at one end in the width direction, but at about one-third of the width. It should be noted, however, that even with this configuration, the requirement - inside tight, outside less dense - is met.

9 shows an eighth advantageous embodiment of the invention, that of 8th is similar. Here, however, the thickness of the joint sealing tape remains 10 at the third section 13 to about the middle in the width direction constant, then rounded and with greater steepness than in the seventh embodiment to a maximum in the fourth section 14 rise again and then - again with greater steepness - back to the same value as in the third section 13 drop. In this as in the seventh embodiment, it is not important that the thickness of the joint sealing strip 10 At the edge shown here on the left, exactly the same as in the edge shown on the right (in the third section) 13 ) or something bigger or smaller, but that the thickness in the fourth section 14 - even if this is not on the edge - greater than that in the third section 13 is.

In 10 a ninth embodiment is shown in which the thickness of the joint sealing tape 10 from a third section 13 starting even initially drops, and linearly, then about a third in the width direction linear again up to the fourth section 14 to increase. It should be noted that in this embodiment, the third section 13 and the fourth section 14 directly on the edge with respect to the width direction of the joint sealing tape 10 are located.

According to the in 11 shown tenth embodiment, the thickness falls from the edge in the width direction of the joint sealing tape 10 located third section 13 initially linear and then increases linearly to a maximum in the fourth section 14 at. Unlike the ninth embodiment, in the tenth embodiment, the fourth section is located 14 not on the edge in the width direction of the joint sealing tape 10 , but only with respect to the edge offset by about 1/4 to 1/5 of the width inwards. After the maximum in the fourth section 14 then the thickness drops again. It should be noted, however, that in both the ninth and tenth embodiments, the thickness of the sealing element 10 in the third section 13 (This is usually the outside facing portion) is less than in the area of the fourth section 14 (which usually faces the inside). Of course, in the two last-mentioned embodiments, the transitions from the respective taper of the thickness and its enlargement and vice versa can also be rounded, as has been described and illustrated, for example, in connection with the third, seventh and eighth embodiments. In any case, however, the indispensable for the functioning of the jointing invention profiling of the joint sealing strip or sealing element is maintained that the latter must be inside denser than outside. It should be clear that it is not so much on the distinction inside / outside, but on the milieu, which usually prevails there. In other words, for example, the sealing element of the invention should be installed "wrong" around when it is usually warmer outside than inside, as is the case for example in a cold store.

In 12 the structure of a thermally insulated system according to the invention is shown schematically. Between a door frame 42 which is intended to be an example of the edge region of a component, and a masonry 44 , which is to be exemplary of the connection area of a building, vehicle or the like, is a joint sealing tape 10 used. The joint sealing tape 10 extends as shown in 12 in the width direction from left to right, with the left edge of a first section 11 and the right edge of a second section 12 is formed. In the arrangement shown here is the joint sealing tape 10 homogeneous with thermoexpandable particles 50 interspersed, starting from a left and right same temperature. Depending on which side after a temperature change, the temperature is higher, the particles will 50 expand more and thus the joint sealing tape 10 give a stronger sealing effect.

It should be noted that the features of the invention described with reference to the illustrated and described embodiments, such as type and size of the thermo-expandable substances used, the nature and design of changes in the thickness of the joint sealing tape or the sealing element or its exact arrangement between the edge region and Terminal area, even in other embodiments may be present, unless otherwise stated or for technical reasons forbids itself.

LIST OF REFERENCE NUMBERS

10

 Fugendichtband / sealing element

11

 first section

12

 second part

13

 third section

14

 fourth section

15

 step

18, 19

 installation edge

30

 Another joint sealing tape / sealing element

42

 Frame / edge area of a component

44

 Masonry / connecting area of a building or vehicle

50

 Particle / thermo-expandable substance

Claims (21)

Sealing element ( 10 ), in particular joint sealing tape, for the sealing of a border area ( 42 ) of a component against an adjacent connection region ( 44 ) of a building, vehicle or the like, wherein the sealing element ( 10 ) is formed from a polyurethane flexible foam and contains at least one thermoexpandable substance, wherein the at least one thermoexpandable substance is homogeneously in the sealing element ( 10 ), whereby at such changing temperature conditions, that the cold side of the sealing element ( 10 ) once on the inside and then again on the outside of the sealing element ( 10 ) is always ensured that a warm side of the sealing element ( 10 ) better than a cold side of the sealing element ( 10 ), wherein the thermoexpandable substance is formed from nanoparticles, wherein the thermoexpandable substance comprises particles having a particle size of 1-100 nm. Sealing element ( 10 ) according to claim 1, wherein the at least one thermo-expandable substance comprises particles having a particle size of 2-50 nm, in particular about 20 nm. Sealing element ( 10 ) according to one of the preceding claims, wherein it has a density of between 20 and 300 kg / m ³ , preferably between 40 and 200 kg / m ³ , in particular about 70 kg / m ³ . Sealing element ( 10 ) according to one of the preceding claims, wherein it has a cell structure with at least 20 cells per cm length of the sealing element ( 10 ), preferably with at least 25 cells per cm length of the sealing element ( 10 ), having. Sealing element ( 10 ) according to one of the preceding claims, wherein the apparent density of the flexible polyurethane foam is between 10 and 60 kg / m ³ , preferably between 18 and 50 kg / m ³ , in particular about 28 kg / m ³ . Sealing element ( 10 ) according to one of the preceding claims, wherein the air permeability of the flexible polyurethane foam does not exceed a value of 150 l / m ² s, preferably a value of 100 l / m ² s. Sealing element ( 10 ) one of the preceding claims, wherein the sealing element ( 10 ) between a first section ( 11 ) and a second section ( 12 ) extends in a width direction, which the boundaries of the sealing element ( 10 ) in the width direction, as well as transversely to the width direction in a thickness direction depending one the edge region ( 42 ) and the connection area ( 44 ) facing mounting edge ( 18 . 19 ), wherein the two mounting edges ( 18 . 19 ) are at least substantially plane-parallel. Sealing element ( 10 ) according to one of claims 1 to 6, wherein the sealing element ( 10 ) between a first section ( 11 ) and a second section ( 12 ) extends in a width direction, which the boundaries of the sealing element ( 10 ) in the width direction, as well as transversely to the width direction in a thickness direction depending one the edge region ( 42 ) and the connection area ( 44 ) facing mounting edge ( 18 . 19 ), and the sealing element ( 10 ) is profiled in such a way that, in the area of the first section ( 11 ) has a greater thickness than in the region of the second section ( 12 ). Sealing element ( 10 ) according to claim 8, wherein it is profiled in such a way that, in the absence of external influence in the region of the first section (FIG. 11 ) has a greater thickness than in the region of the second section ( 12 ), and so compressible is that its thickness from the first section ( 11 ) to the second section ( 12 ) when installed between the edge region ( 42 ) and the connection area ( 44 ) is substantially the same. Sealing element ( 10 ) according to claim 8 or 9, wherein in the absence of external action, the thickness of the second section ( 12 ) to the first section ( 11 ) monotonically increases. Sealing element ( 10 ) according to one of Claims 8 to 10, in which, in the absence of external action, the thickness of the sealing element ( 10 ) between the mounting edges ( 18 . 19 ) of the second section ( 12 ) to the first section ( 11 ) increases at least partially linearly. Sealing element ( 10 ) according to one of claims 8 to 11, in which in the region of the second section ( 12 ) a third section ( 13 ) of the sealing element ( 10 ) with a thickness first in the absence of external action and in the region of the first portion ( 11 ) a fourth section ( 14 ) is provided with a second value of the thickness which is greater than the first value of the thickness in the absence of external action, wherein in the absence of external action the thickness of the third portion ( 13 ) to the fourth section ( 14 ) increases monotonously. Sealing element ( 10 ) according to one of claims 8 to 11, in which in the region of the second section ( 12 ) a third section ( 13 ) of the sealing element ( 10 ) with a thickness first in the absence of external action and in the region of the first portion ( 11 ) a fourth section ( 14 ) is provided with a second value of the thickness which is greater than the first value of the thickness in the absence of external action, wherein in the absence of external action the third portion ( 13 ) and the fourth section ( 14 ) to form a stage ( 15 ) directly adjoin one another. Sealing element ( 10 ) according to one of Claims 8 to 9, in which, in the absence of external action, the thickness of the sealing element ( 10 ) of the second section ( 12 ) to the first section ( 11 ) increases and then decreases again. Sealing element ( 10 ) according to claim 14, wherein in the absence of external action, the thickness of the sealing element ( 10 ) from about midway between the first section ( 11 ) and the second section ( 12 ) increases. Sealing element ( 10 ) according to one of Claims 8 to 9, in which, in the absence of external action, the thickness of the sealing element ( 10 ) of the second section ( 12 ) to the first section ( 11 ) and then increases again, its thickness at the second section ( 12 ) is smaller than on the first section ( 11 ). Sealing element ( 10 ) according to one of Claims 8 to 9, in which, in the absence of external action, the thickness of the sealing element ( 10 ) of the second section ( 12 ) to the first section ( 11 ) decreases, then increases again and finally decreases again, its thickness at the second section ( 12 ) is smaller than on the first section ( 11 ). Sealing element ( 10 ) according to one of claims 7 to 17, in which the two mounting edges ( 18 . 19 ) symmetrical with respect to one of the first section ( 11 ) to the second section ( 12 ) extending axis are formed. Sealing element ( 10 ) according to one of claims 7 to 17, wherein one of the mounting edges ( 19 ) is formed without profile, wherein preferably at the profillos trained mounting edge ( 19 ) another sealing element ( 30 ) is mounted with a profiled trained mounting edge. Sealing element ( 10 ) according to one of the preceding claims, in which the sealing element ( 10 ) is impregnated homogeneously with a flame retardant-containing impregnating substance. A thermally insulated system comprising a structural element, such as a door, a window or the like, with a peripheral area ( 42 ), a connection area ( 44 ), to the border area ( 42 ), in a building, vehicle or the like, and a sealing element ( 10 ), in particular a sealing element ( 10 ) according to one of claims 1 to 20, for the sealing of the edge region ( 42 ) against the adjacent connection area ( 44 ), wherein the sealing element ( 10 ) is formed from a polyurethane flexible foam and contains at least one thermoexpandable substance, wherein the at least one thermoexpandable substance is homogeneously in the sealing element ( 10 ), whereby at such changing temperature conditions, that the cold side of the sealing element ( 10 ) once on the inside and then again on the outside of the sealing element ( 10 ) is always ensured that a warm side of the sealing element ( 10 ) better than a cold side of the sealing element ( 10 ), wherein the thermoexpandable substance is formed from nanoparticles, wherein the thermoexpandable substance comprises particles having a particle size of 1-100 nm.

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