Patent Grant
8590261
This application claims priority based on European patent application EP 11 185 762.9 filed Oct. 19, 2011.
The present invention relates to a method for sealing of replacement windows.
When windows are being replaced, the usual procedure is first to remove the old window from the masonry wall by the use of, for example, a suitable window joint saw. Both the interior plastering and the exterior rendering are separated from the old window frame along a straight, sharply defined line and the old window frame is then taken out. As a result, the old window which has been removed leaves behind, on all sides, a channel-shaped recess between the interior plastering and the exterior rendering. This recess extends all the way to the rough masonry and can even penetrate into it. Such recesses vary in depth and are usually 10-100 mm deep.
Modern window frames are usually wider than old window frames, which means that, when a new window is being installed, the window frame cannot be inserted into the recess but rather must remain outside it. The recess extending all the way around must be filled with a sealing and insulating material, so that, after the new window has been installed, the space between the bottom of the recess and the new window frame is sealed in a manner consistent with good building insulation as defined by the generally recognized rules of the technology.
Injected polyurethane foams or mineral fiber insulating materials, for example, have been used in the past to seal these recesses. Sealing tapes of flexible foam are also used.
In the case of the latter option, flexible foam sealing tapes are attached directly to the new window frame. For example, a window frame equipped with a flexible foam sealing tape is known from US 2011/0185661 A1. The sealing tape can be held in place between the opposing angled edges of two molding profile strips on the window frame. This is done by introducing the stiff layer, on which the flexible foam is mounted, into the intermediate space between the molding profile strips, where it is prevented from slipping out of position by the angled edges. The stiff layer is then destroyed to release the foam, which can finally expand and seal the window frame in the direction toward the masonry. In the case of the previously mentioned process of window replacement, however, it is very difficult to reach the stiff layer after the new window frame has been brought into the desired installation position, and it is also impossible to see whether or not the recess has been sealed completely with the flexible foam strip.
According to US 2011/0143122 A1 and US 2011/0302873 A1, the sealing tape again comprises a layer of flexible foam and a stiff layer. Here, the stiff layer does not have to be destroyed to release the flexible foam, and the flexible foam is arranged on the side of the stiff layer facing the masonry. The stiff layer can be premounted in profiled channels in the window frame by the use of various fastening mechanisms. However, it is still impossible to see whether or not the recess has been sealed completely with the flexible foam strip.
In summary, the combination of a window frame with a sealing tape already premounted on it is not optimally suitable for the window replacement process described above.
It is an object of the present invention to provide a method for sealing of replacement windows by means of which the sealing of the new window frame in the masonry can be ensured efficiently and reliably, and which at the same time can be carried out easily by the tradesman.
According to an aspect of the invention, the method for sealing of replacement windows comprises the steps of:
whereupon the first layer of the sealing tape expands further or is allowed to expand further until the sealing tape rests against the window frame.
With a method such as this, it is possible to ensure that a channel-shaped recess in a masonry wall can be sealed or insulated completely and reliably without impeding the installation of the new window frame.
As outlined above, during the period in which the expansion of the first layer of the sealing tape is being at least temporarily limited, a window frame is placed in the area of the recess filled by the sealing tape. In this way, a two-stage process is created, according to which the channel-shaped recess in the masonry is first provided with the sealing tape, which is held at least temporarily in the partially compressed state and which does not expand against the window frame until after the window frame has been put in place.
In a first embodiment, the retaining elements comprise screws or nails, which are driven through the sealing tape and anchored in the bottom or side walls of the recess after the sealing tape has been fitted into the recess, wherein the heads of the screws or nails exert a retaining function on the second layer of the sealing tape. In this way, the stiff layer of the sealing tape is connected reliably and permanently to the masonry at a fixed distance to the bottom.
In another preferred embodiment, the retaining elements comprise flat retaining strips, which exert the retaining function on the second layer of the sealing tape. In this way, the sealing tape can be held flat in a partially compressed state without interfering with the installation of the new window frame.
In an elaboration of this embodiment, the retaining elements comprise, in addition to the retaining strips, screws or nails which, after the sealing tape has been fitted into the recess, are driven through the sealing tape and anchored in the bottom or side walls of the recess, wherein the heads of the screws or nails project slightly from the second layer of the sealing tape. The flat retaining strips, furthermore, comprise an opening in their middle section and are arranged between the heads of the screws or nails and the sealing tape, wherein the middle section of the flat retaining strips rests against the heads of the screws or nails from underneath after the retaining strips have been installed. Thus the function of retaining the sealing tape in the recess is ensured at several points, and simultaneously the sealing tape is kept in a predetermined state of expansion, whereas, after the new window frame has been put in place, the flat retaining strips can be easily removed, so that the sealing tape can expand all the way to the window frame.
The two side sections of the flat retaining strips preferably rest on the masonry, one on each side of the recess, after the retaining strips have been installed in order to define the exact location of the retaining strips.
In an alternative embodiment, the deliberate release of the retaining function is achieved by pulling on at least one laterally projecting pull element, which exerts a force on the second layer. The pull element is preferably permanently bonded to the second layer of the sealing tape, and it can be designed in the form of, for example, a sheet-like pull tab.
The sealing function and handling of the sealing tape can be further improved by making the second layer of the sealing tape out of stiff foam.
In an alternative embodiment, the second layer of sealing tape can comprise clamping sections projecting beyond the first layer of the sealing tape on both sides to clamp the tape against the side walls of the recess. As a result, regardless of the form and surface condition of the side walls of the recess, the sealing tape can be securely clamped in the recess without the use of any other aids.
To facilitate handling, the first layer and the second layer of the sealing tape are preferably permanently bonded to each other.
To improve the sealing properties and to allow the sealing tape to rest more closely against the contours of the installed window frame, the sealing tape preferably comprises a third layer of flexible foam, which is permanently bonded to the second layer of the sealing tape on the side of the second layer opposite the first layer.
To ensure that the recess is effectively sealed and that the flexible foam rests closely against the contours of the bottom of the recess even if those contours are irregular, the first layer of the sealing tape comprises, in special embodiment, a plurality of 3-dimensional foam segments, which are separated from each other by cuts, which extend from the top, i.e., from the side facing away from the second layer of the sealing tape, into the first layer of the sealing tape, wherein, when the first layer is in the expanded state, the foam segments extend over at least 50% of its height, preferably over at least 60% of its height, more preferably over at least 70% of its height, and even more preferably over 90% of its height.
To simplify production and to create uniform foam segments, a plurality of cuts is preferably substantially parallel to the side walls of the recess, and another plurality of cuts is substantially perpendicular to the side walls of the recess, so that the foam segments comprise a rectangular outline. Alternatively, the cuts can extend at an angle to the side walls of the recess, so that the foam segments comprise a rhombic outline. Other geometric forms are also conceivable, as is the use of dimpled foam.
Additional features and advantages of the invention can be derived from the following description, which refers to the drawings.
a-2c are cross-sectional views of the masonry wall of
a-6c are cross-sectional views of the masonry wall of
d is a top view of an embodiment of a retaining strip of the type which can be used in the method according to
e is a top view of the masonry wall in the step of the sealing process according to
a is a cross-sectional view of the masonry wall of
b is a perspective view of the retaining clips used in
Recesses 4 of this type in masonry 2 are usually encountered when a window is being replaced, that is, when the old window frame is cut out of masonry wall 2 with a window joint saw and removed. When the previously mentioned saw is used, side walls 12 of the resulting recess 4 are usually relatively smooth, whereas bottom 10 of recess 4 can be quite bumpy. It is obvious that recess 4 extends all the way around the opening and that the cross-sectional view in
The height of masonry 2 on one side of recess 4 can also be offset from that of masonry 2 on the other side of recess 4 (not shown), thus creating, for example, an outside stop for the window.
Sealing tape 16 is now introduced into the recess, as shown in
Sealing tape 16 consists of a first layer 18 of flexible foam, which, in the expanded state, has a thickness in the range of 5-150 mm, preferably of 20-100 mm, and a width in the range of 10-250 mm, preferably of 40-100 mm.
First layer 18 of the sealing tape can be made of any desired open-cell or closed-cell flexible foam such as polyurethane or polyethylene foam which recovers after compression. The foam can be impregnated to delay its recovery after compression. The density of flexible foams of this type is usually in the range of 20-200 kg/m3.
A second, thinner stiff layer 20 of the sealing tape is arranged on the bottom side of first layer 18 of the sealing tape. Second layer 20 is bonded to first layer 18 preferably by means of an adhesive or by lamination. The thickness of second layer 20 is in the range of 1-10 mm, preferably of 2-5 mm.
A foam of greater, preferably of much greater, stiffness than the flexible foam of first layer 18 is preferably provided as a material for second layer 20. For the stiff foam of second layer 20, therefore, plastics of foamed polyethylene or polypropylene can be considered. The stiff foam offers significant advantages especially in cases where sealing tape 16 is clamped in recess 4 without the use of additional fastening means (as shown in
The material of second layer 20 could also be a stiff material such as a nonwoven or mesh material. Strips of plastic or some other material which is suitable for the purpose indicated could also be used. Combinations of the materials mentioned above are also possible.
It is also possible to divide second layer 20 into two or more subsections arranged in series, these subsections not being attached to each other. It is also possible for two adjacent subsections of second layer 20 to be arranged a certain distance apart, so that the material of first layer 18 can expand into the resulting intermediate spaces and thus act as a kind of “shock absorber” between the two subsections of second layer 20.
Second layer 20 generally has a flexural strength of more than 200 kPa, preferably of more than 250 kPa. In a preferred embodiment, second layer 20 has a flexural strength of more than 300 kPa, preferably of more than 400 kPa. In an especially preferred embodiment, second layer 20 has a flexural strength of more than 500 kPa, preferably of more than 1,000 kPa, and even more preferably of more than 2,000 kPa. At the same time, the material of second layer 20 must be elastic enough not to break during the application according to the invention. 10,000 kPa, for example, represents an upper limit for the flexural strength.
The foam material of first layer 18, however, has a flexural strength of less than 150 kPa, preferably of less than 125 kPa, and more preferably of less than 100 kPa. In any case, however, it will always be more than 0 kPa.
The flexural strengths of the material of second layer 20 and of first layer 18 are determined on the basis of the standard ISO 1209-2, third edition, of 2007. This international standard is usually used to measure the flexural strength of plastics, but in somewhat modified form it is also an excellent way of measuring the flexural strength of foams.
A uniformly changing force is applied perpendicularly to the middle of a test piece extending between two support points. The flexural strength is calculated from the measured force-versus-deformation curve (see Section 3 of ISO 1209-2). The test apparatus is shown in greater detail in Section 4,
The support points consist of two parallel cylindrical support elements, which are arranged horizontally in the same plane and each of which has a radius of 15±1 mm. The length of the support elements is greater than the width of the test pieces. In the present case, the support elements are 80 mm long.
The distance L between the support elements for the present measurement deviates from that of ISO 1209-2 and is fixed instead at 85±2 mm. The force-transmitting element has the same shape as the support elements. The other dimensions given in Section 5.1 of ISO 1209-2 are adjusted for the special purpose of measuring foams. Each measured foam test piece is a block with a length l of 150±3 mm, a width b of 40±2 mm, and a thickness d of 3.0±0.2 mm. Of the sets of test conditions described in Section 6 of ISO 1209-2, the first is used. That is, the measurement is carried out at a temperature of 23±2° C. and at a relative humidity of 50±10%. Instead of the velocity value given for the movement of the force-transmitting element in Section 7 of ISO 1209-2, a velocity of only 10±1 mm per minute is used here. In addition, the force is measured up to a maximum deflection of the foam of 20 mm, and the maximum value FR of the force observed during the course of the measurement is recorded.
The calculation of the flexural strength R (in kPa) is described in Section 8.1 of the ISO 1209-2, i.e. the formula R=1.5 FR·L/bd2·106 is used, where FR is the maximum applied force in kN, L is the distance between the support elements in mm, b is the width of the test piece in mm, and d is the thickness of the test piece in mm.
For the values of L, b, and d given above, the results cited above for the material of second layer 20 and for that of the first layer 18 are obtained from the measured force FR.
First layer 18 of the sealing tape can be designed as a one-piece foam block, as shown in
For certain applications, it can be advantageous for sealing tape 16 to comprise several foam segments 26, as shown in
All of cuts 28 extend from the top side 30 into first layer 18 of the sealing tape. When first layer 18 of the sealing tape is in the expanded state, cuts 28 and thus foam segments 26 extend over at least 50% of the height of the layer, preferably up to at least 90% of its height. In the area of the bottom side of first layer 18 of the sealing tape, a web 32 can remain, which connects foam segments 26 to each other. This web 32 is separated in
In the present example, one set of cuts 28 is substantially parallel to side surfaces 22 of first layer 18 of the sealing tape (and thus also, in the expanded state of
In addition to the design and direction of cuts 28 shown here, many other designs are also conceivable. For example, cuts 28 can extend at an angle or in zigzag fashion through sealing tape 16; they could also be wave-like or have any other desired, preferably regular, configuration. Accordingly, the shape of the individual foam segments 26 can also deviate from the block-like shape shown in
Cuts 28 are usually extremely narrow, and they are produced by displacement cutting, i.e., a form of cutting which does not result in the loss of any material when cuts 28 are made in foam strip 18. It is also possible to produce cuts 28 by punching foam material out of strip 18, if this is deemed advantageous for certain applications. As a rule, however, it is preferable to make cuts 28 as narrow as possible and to lose as little material as possible when making cuts 28, so that the sealing action of sealing tape 16 remains as strong as possible.
Cuts 28 could also extend over the entire height of first layer 18 of the sealing tape, so that the individual foam segments 26 are connected to each other only by second layer 20.
As can be seen from
Second layer 20 of the sealing tape in the variant shown here has also been introduced through open access section 14 of the recess and has clamped itself against side walls 12 of recess 4. As a result, the expansion of the partially compressed first layer 18 of the sealing tape in recess 4 is at least temporarily limited in the direction toward open access section 14. Clamped second layer 20 of the sealing tape thus at least temporarily prevents first layer 18 from expanding further.
As can be seen in
After a certain period of time, the clamping action of second layer 20 against side walls 12 of recess 4 yields to the expansion pressure of first layer 18, so that second layer 20 is slowly pushed along side walls 12. Sealing tape 16 thus expands more and more toward window frame 24 until it finally rests against window frame 24. In this final installation state, first layer 18 of the sealing tape still has a certain expansive force, so that a reliable seal is ensured both in the direction toward window frame 24 and also in the direction toward bottom 10 of recess 4. Additional sealing elements 34 or sealants can also be inserted or injected between window frame 24 and masonry wall 2 on one or both sides of sealing tape 16. Alternatively, the still visible joint between masonry 2 and window frame 24 can be covered by a strip of plastic, for example.
To ensure the defined expansion of the sealing tape at the desired time, a flat, angled tool can be inserted between side wall 12 of recess 4 and second layer 20 and then used to lever second layer 20 upward along its edge.
In the variants shown in
a-6e show another preferred variant of the method according to the invention. First, sealing tape 16 is again fitted into recess 4. Then flat retaining strips 46 are attached as retaining elements over the open access section 14 of recess 4 to exert a retaining function on second layer 20 of the sealing tape and thus temporarily to prevent first layer 18 of the sealing tape from expanding further. Flat retaining strips 46 can be made of, for example, wood, metal, or plastic, and they comprise a thickness in the range of 0.5-5 mm. After sealing tape 16 has been fitted into recess 4, flat retaining strips 46 in the example shown here are anchored by means of screws 48 or nails in bottom 10 of recess 4 (or alternatively on the left and right of the recess, near side walls 12). When screws 48 are used, it is necessary again to produce pilot holes 50 in masonry 2, wherein, in a preferred embodiment, sealing tape 16 has already been provided with appropriate through-openings at these points. Screws 48 or nails are screwed into bottom 10 of recess 4 until their heads 52 press against flat retaining strips 46, and after retaining strips 46 have been installed, two side sections 54 of flat retaining strips 46 rest against masonry 2, one on each side of recess 4. In this way, flat retaining strips 46 exert a retaining function on second layer 20 of sealing tape 16, which presses against retaining strips 46. Flat retaining strips 46 can be placed on sealing tape 16 even before screws 48 or nails are introduced, or they can be inserted locally between second layer 20 of the sealing tape and heads 52 of screws 48 after screws 48 have been screwed in. In the installed state, therefore, heads 52 of screws 48 or nails project slightly outward from second layer 20 of sealing tape 16, namely, by a distance which is defined by the thickness of retaining strips 46.
d shows by way of example an embodiment of retaining strip 46. The middle section 56, which is located between the two side sections 54, serves here, after installation of retaining strips 46, to rest against heads 52 of screws 48 or nails from underneath. In the preferred embodiment shown here, flat retaining strip 46 comprises in its middle section 56 an opening 58, which serves to accept the shaft of screws 48 or nails. Opening 58 is preferably open to the side and expands toward the outside. After window frame 24 has been put in place (see
Especially the number and shape of retaining strips 46 can be varied in many different ways. The distances between individual retaining strips 46 also depend on the expansive force of sealing tape 16 and can be varied.
a and 7b show another way in which sealing tape 16 can be held temporarily in place in recess 4. For this purpose, retaining elements in the form of retaining clips 60 are used, which are shown in greater detail in
The retaining function is released in this case by, for example, breaking off the head sections 64 or by turning head sections 64 by 90° so that head sections 64 become oriented parallel to the intermediate space between sealing tape 16 and side wall 12 of recess 4 and thus no longer prevent sealing tape 16 from expanding.
Many other embodiments of retaining clips 60 are possible. These can also be fastened permanently to masonry 2 by the use of screws, for example. They could also cover the entire sealing tape 16.
As a rule, the retaining casing will have to have at least three retaining strips 46 connected to each other like the arch of a door in order to cover the left side, the right side, and the top of the window opening.
Pull tab 66 is permanently bonded to second layer 20 of sealing tape 16, preferably by an adhesive or by lamination. In the example shown here, pull tab 66 is guided laterally under second layer 20 and attached there to the bottom edge. Pull tab 66 could also be attached to the side or to the top of second layer 20.
The deliberate release of the retaining function is achieved now by pulling the at least one pull tab 66, as a result of which a section of second layer 20 or entire second layer 20 is raised toward the open access section 14. Thus the clamping action of second layer 20 against side walls 12 of recess 4 is released, and the attempt by first layer 18 of sealing tape 16 to expand is no longer restrained at all or at least no longer significantly restrained.
The term “sheet-like” includes, for example, any tear-resistant sheet-like material, mesh material, laminated material made of plastic sheets laminated to a backing (e.g., nonwoven material), and fabric-reinforced sheets. Combinations of these materials are also possible.
In the case of
If pull tab 66 is attached to the top of second layer 20, it is advantageous to design it as an integral part of that layer and to provide it with two pull sections, one projecting to each of the two sides, which can be pulled simultaneously in opposite directions in order to raise the second layer toward open access section 14.
In the embodiments according to
To release the clamping action when desired, it is necessary merely to pull on the two pull sections of thin strip 74 simultaneously in opposite directions. As a result, first layer 18 of sealing tape 16 is compressed, and then second layer 20 is raised toward open access section 14. After thin strip 74 has been removed by pulling it out laterally, first layer 18 of sealing tape 16 can expand again toward bottom 10 of recess 4.
The same materials as those suitable for pull tab 66 can be used for thin strip 74. In this case as well, it is also possible to arrange, instead of thin strip 74, several narrow pull elements spaced a certain distance apart in the longitudinal direction of recess 4, which can be designed as cords, for example.
In the example shown here, pulling on a tab of clamping aid member 76 projecting laterally out of recess 4 has the effect of unrolling the clamping aid member and finally of pulling it out of recess 4, as a result of which the clamping action of second layer 20 in recess 4 is released and first layer 18 is free to expand.
A number of other embodiments of the method according to the invention can also be imagined. The important point in all cases, however, is that sealing tape 16 is inserted into channel-shaped recess 4 in masonry 2, where, either through direct or indirect clamping of second layer 20 against side walls 12 of recess 4 or by means of a plurality of retaining elements, several examples of which have been described and which exert a retaining force on second layer 20 of the sealing tape, the expansion of first layer 18 of sealing tape in recess 4 is at least temporarily limited, whereupon window frame 24 is installed in the area of recess 4 filled by sealing tape 16.
In addition to window replacement, the method according to the invention can also be used to seal other channel-shaped recesses 4 in masonry 2.
In addition to the retaining elements described above, there are also other possibilities, such as the use of retaining clamps (shot technique), chemical fixation of sealing tape 16 in recess 4, etc. The sealing tape can also comprise more than the number of layers described here.
It is also possible to arrange several first layers 18 next to each other on a second layer 20. These several first layers 18 can be arranged directly adjacent to each other or a certain distance apart. The several first layers can all be made of the same material, or they can consist of different materials. The latter option offers advantages, for example, when the permeability to air or vapor diffusion in the inner area is to be different from that in the outer area of the masonry wall (“inside tighter than outside”).
Finally, second layer 20 can comprise longitudinal edge profiling in the form of waves or a zigzag pattern or have some other geometric form. This can make it possible to adjust the clamping force of second layer 20 against side walls 12 of recess 4 more precisely, and at the same time it decreases the resistance of second layer 20 as sealing tape 16 is being inserted into recess 4.
Second layer 20 can also be provided with longitudinal, diagonal, or transverse cuts to increase its elasticity, to adapt its width, and to regulate the transverse tension in specific areas.
Reference throughout this specification to “the embodiment,” “this embodiment,” “the previous embodiment,” “one embodiment,” “an embodiment,” “a preferred embodiment” “another preferred embodiment” “the example,” “this example,” “the previous example,” “one example,” “an example,” “a preferred example t” “another preferred example” or similar language means that a particular feature, structure, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. Thus, appearances of the phrases “in the embodiment,” “in this embodiment,” “in the previous embodiment,” “in one embodiment,” “in an embodiment,” “in a preferred embodiment,” “in another preferred embodiment,” “in the example,” “in this example,” “in the previous example,” “in one example,” “in an example,” “in a preferred example,” “in another preferred example,” and similar language throughout this specification may, but do not necessarily, all refer to the same embodiment.
Furthermore, the described features, advantages, and characteristics of the invention may be combined in any suitable manner in one or more embodiments or examples. One skilled in the relevant art will recognize that the invention may be practiced without one or more of the specific features or advantages of a particular embodiment or example. In other instances, additional features and advantages may be recognized in certain embodiments or examples that may not be present in all embodiments of the invention.
While the present invention has been described in connection with certain exemplary or specific embodiments or examples, it is to be understood that the invention is not limited to the disclosed embodiments or examples, but, on the contrary, is intended to cover various modifications, alternatives, modifications and equivalent arrangements as will be apparent to those skilled in the art. Any such changes, modifications, alternatives, modifications, equivalents and the like may be made without departing from the spirit and scope of the invention.
| Number | Date | Country | Kind |
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| 11185762 | Oct 2011 | EP | regional |
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| Number | Date | Country | |
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| 20130097963 A1 | Apr 2013 | US |
