NO325789B1 - Ceiling ventilation band - Google Patents

Description

The invention relates to a ventilation band for a roof, for installation in the ridge, hip or ridge area, with an attachment area, at least one outer sealing area and at least one ventilation area arranged between the sealing area and the attachment area, the ventilation area having several in the direction along the longitudinal axis of the ventilation band arranged ventilation openings, each of the ventilation openings being arranged in a collar-shaped bulge.

Ventilation bands of this type, which in practice are also referred to as air bands, serve to effect ventilation of the inner space in the ceiling. The venting effects of this ventilation band occur when the ventilation area is bypassed by a flow from outside. Due to the air flow over the ventilation area, a relatively high dynamic pressure and a correspondingly low static pressure occur there. In contrast, the flow rate of the air below the ventilation band is relatively small, so that a less dynamic and a correspondingly higher static pressure occurs there. Due to these pressure conditions, a static negative pressure occurs above the ventilation band, so that air and condensation moisture from the inner space in the ceiling is sucked outwards, and thus a venting of the inner space in the ceiling occurs.

In order to achieve a sufficient venting effect for the ventilation band, it is first necessary that a sufficient seal has been achieved between the cover plates on the roof and the ventilation band over the inner sealing area. If there is insufficient sealing in this area, the influx of air and moisture over the space between the ventilation band and the cover plates on the roof can penetrate into the inner space in the roof, so that instead of the desired ventilation of the inner space in the roof, a unwanted ventilation and possibly also ingress of moisture. However, preventing the ingress of moisture is not only important in the transition between the ventilation strip and the cover plates on the roof, as it must also be prevented that rain or snow enters the inner space of the roof through the ventilation openings.

A ventilation band of the type described above is known from DE patent documents

196 02 979. To prevent the ingress of moisture through the ventilation openings, a circumferential collar is arranged around each ventilation opening that protrudes outside the ventilation area. This collar can be designed in one with the ventilation area or as a separate insert, which is inserted into the ventilation area. This requirement must ensure that, in the event of strong winds, any water that comes under the ridge stones flows over the upper side of the ventilation band to the adjacent cover plates on the roof, without dripping into the roof through the ventilation ducts. The same applies to incoming drifting snow

in. Incidentally, such a collar also produces a spoiler function, so that the venting effect of the ventilation band is further improved. With the known ventilation band, it may possibly occur in very strong winds that water or snow enters the ventilation opening through the collar, so that in this way an unwanted penetration of moisture into the inner space in the roof occurs.

From EP A1 0791699, a ventilation band is known for use in e.g. another a ridge area, equipped with ventilation openings and openings with a circumferential collar stepped at different heights.

From EP A1 0724048 it is known to equip a ventilation band with channel-shaped edge devices.

The task of the present invention is to come up with a ventilation band of the type described above, with which, even in very strong winds, unwanted ingress of moisture can mainly be prevented.

The stated task is solved according to the invention mainly by having at least one circumferential, collar-shaped bulge arranged inside the collar, so that a circumferential collector channel is arranged between the collar and the bulge.

With the design according to the invention, at least one additional barrier is thus formed which prevents moisture penetration, even when water is driven past the outer collar by strong air flow. Crucial in this context is that there is a collecting channel between the collar and the bulge which is not immediately exposed to the air flow that is carried along the upper side of the ventilation band, so that water which is located between the collar and the bulge and which has collected there is not driven directly into the ventilation opening . It is particularly advantageous in this context that the collector channel located between the collar and the bulge is circular, so that it extends around the entire bulge, so that the collector channel has a relatively large absorption volume.

In order to prevent unwanted ingress of moisture in all cases, even with an all-round collecting channel, the bulge with the ventilation opening on the upper side protrudes above the collar. This elevation of the bulge in relation to the collar, which can amount to a few millimetres, not only results in a spoiler effect, but in each case also causes water coming out of the collector channel to flow to the ventilation area and not penetrate into the ventilation openings.

In order to improve the spoiler function of the ventilation band according to the invention in the area of the ventilation openings, the walls of the bulge which extend in the direction along the longitudinal axis of the ventilation band are inclined towards each other, the angle of inclination in the area of the walls should be greater than 45° and less than 90° in relation to the horizontal direction. When choosing an angle, it should be ensured that it is not too small, as this increases the risk of water ingress, but that it is also not too large, as this can have an adverse effect on the air flow in the area of the ventilation openings.

For manufacturing and handling technical reasons, the collar-shaped bulge can be designed in one with the ventilation area, respectively the ventilation band. With the uniform design, it is ensured that no subsequent arrangement of inserts is needed and that these cannot be lost, e.g. when placing the ventilation tape.

The aforementioned uniform design can particularly be used when the attachment area, the ventilation area and the sealing area are also designed as one with the ventilation band and consist of such a material that the ventilation band can be rolled up in the direction along the longitudinal axis. A rolled-up longitudinal band can be placed very easily, in that it only has to be unrolled and aligned at the place of placement. Incidentally, with such a rolled up ventilation band, relatively long air bands can be formed.

In order to be able to roll up the ventilation bands according to the invention in a simple way and to be able to easily adapt the sealing area to the profile of the cover plates on the roof, the material in the ventilation band preferably consists of soft PVC, which should be resistant to ultraviolet radiation.

For a ventilation band in which the attachment area, the ventilation area and the sealing area are uniformly designed, the sealing area can be equipped with several loops arranged next to each other in the direction along the longitudinal axis of the ventilation band. With these loops, elastic yielding properties are achieved in the sealing area and also a good sealing effect and adaptation to the profile of the covering plates on the roof.

The sealing area is, particularly when the ventilation band is made uniformly of flat material, preferably formed by a cover, the cover being cut to form the loops. The sealing effect of the loops is improved in this context by the fact that the incisions run at an angle between the loops, which leads to the loops being arranged at an angle. The slanted arrangement of the loops prevents the loops from standing up too strongly under certain weather conditions.

Above all, in view of the fact that ventilation tapes of this type are usually rolled up and also stored as a roll, the bulge can be reinforced so that in all cases it is ensured that the ventilation openings in the unsteady state of the ventilation tape retain their original shape, so that it does not occur that the ventilation openings are deformed due to the storage in the coiled state and no longer have a sufficient ventilation cross-section. The reinforcement can e.g. be designed in such a way that the wall of the bulge shows indentations, ribs or waves that run in the height direction of the bulge. This special shape of the wall is favorable for the winding of the ventilation tape and gives the bulge sufficient stability when loaded from above. In terms of flow technology, it has been shown in this context that the wall in the area with indentations, ribs or waves has a stronger slope than the outer area without indentations, ribs or waves.

While according to the known technique it is such that the entire surface limited by the collar forms the ventilation opening, so that ventilation openings with a relatively large cross-section are formed, with a design according to the invention of a comparable type such that the ventilation cross-section is smaller, because not only the ventilation opening is arranged within the collar but also the collar-shaped bulge according to the invention. Constructively, in this context, it is ensured that the distance between two neighboring ventilation openings is greater than or equal to the length of a ventilation opening, while the distance between two neighboring collars is less than the length of a collar. This design with a reduced ventilation cross-section for the ventilation opening compared to known technology has proven to be very positive both in terms of flow technology and also to prevent moisture ingress.

The ventilation openings can otherwise have any shape, but they are preferably designed as elongated holes. This has been proven to give the best aeration results.

It is mentioned at the outset that the transition from the sealing area to the cover plates on the roof is also of great importance to prevent moisture penetration. In the ventilation band according to the invention, in this context it is ensured that at least one adhesive strip is arranged on the underside of the sealing area, continuously in the direction along the longitudinal axis of the ventilation band and that a reinforcement is assigned to the sealing area. Due to the adhesive strip, a secure attachment of the sealing area to the cover plates on the roof can be carried out, and the reinforcement ensures that the installed ventilation strip retains its shape in the sealing area. A particular advantage in this context is that the adhesive strip is equipped with a reinforcement.

The reinforcement is only provided on the adhesive strip and not a direct component of the sealing area. This has not negligible effects on the production of the ventilation band. It is thereby possible to provide an adhesive strip with a corresponding reinforcement at a later date on any ventilation band. The placement of the reinforcement is thus not immediately linked to the manufacturing process for the ventilation strip. Depending on the application, a specific ventilation band can also be equipped with a stiffer reinforcement, in other cases with a softer reinforcement, while the same basic type of ventilation band is used all the time.

Preferably, the reinforcement is embedded in the adhesive strip, so that the adhesive strip which previously performs its adhesive function, and the reinforcement cannot detach from the adhesive strip. In this context, it is optimal that the reinforcement is embedded in the adhesive strip in such a way that the outer adhesive side of the adhesive strip is exclusively formed from material in the adhesive strip. In other words, this means that the reinforcement is not accessible from the outside. Thereby it is achieved that the adhesive strip fulfills its adhesive function over the entire surface, and at the same time, via the reinforcement, a backward movement of the sealing area from the cover plates on the roof is also prevented.

In principle, different materials are suitable as reinforcement, such as e.g. glass fibres, synthetic polymers or stretched metal grids, as they are known from DE 38 16 015 C2. In a particularly simple and cost-effective embodiment, the reinforcement is formed as a single wire insert, which preferably consists of only a single wire. Depending on the desired stiffness in the reinforcement, a thicker or thinner wire can be used.

At the outset, it has already been pointed out that in order to achieve the ventilation function for the ventilation band, it is important that the sealing area can be adapted to the cover plates on the roof, in order to seal the space between the cover plates on the roof and the ventilation band. As the covering plates on the roof can have different profiles, the thread should have the property that it can "expand". This expansion property and thus the property of being able to be adapted to different profiles for the covering material on the roof is achieved according to the invention by the wire being wavy, twisted and/or shaped like a saw tooth. With the specified shape of the wire, a kind of "wire stock" is formed, so that the necessary adaptability of the sealing area to different profiles for the cover plates on the roof is not affected by the wire.

In order to be able to adapt the sealing area with the adhesive layer and the thread to essentially all possible profiles for cover plates on the roof, the length of the thread in the stretched state is at least 1.2 times greater than in the wavy, twisted and/or sawtooth-like state, and it is expedient that the bent shape of the thread is regular, so that the thread e.g. is regularly wavy, so that the "thread supply" is available at almost any place on the thread.

In order to achieve good handling for the ventilation tape according to the invention, a protective foil is arranged on the adhesive side of the adhesive strip. In this way, there is no risk of the ventilation tape sticking to other places before handling and thereby becoming unusable. The protective duty is only removed when the ventilation tape is installed at the place of use and the sealing area is pressed against the profile of the cover plates on the roof during plastic deformation of the thread. The ventilation tape is then raised slightly in the sealing area, and the protective toll is removed from the adhesive layer. This is how the adhesive strip is glued to the cover plates on the roof.

Although it is in principle possible to design the ventilation band according to the invention so that only one ventilation area and one sealing strip are arranged, it is preferred to arrange a ventilation area and a sealing area on both sides of the fastening strip, so that the ventilation band according to the invention in assembled condition can perform its venting function on both sides.

In the following, embodiments of the present invention will be described, with the help of the drawings. Fig. 1 shows in perspective a ventilation band according to the invention in the assembled state.

Fig. 2 shows the underside of the ventilation band according to the invention.

Fig. 3 shows a cross-section of the ventilation band in fig. 2 along the section line III - III in fig. 2.

Fig. 4 shows an image of the incompletely produced ventilation band.

Fig. 5 shows a perspective view of a ventilation tape rolled up into a roll.

In the individual figures, a ventilation band 1 is shown, which is intended for roofs for arrangement in the ridge, hip or ridge area. The ventilation band 1 has a central attachment area 2, two outer sealing areas 3, 4 and between each sealing area 3, 4 and the attachment area 2 a ventilation area 5, 6. As is further evident from the individual figures, each ventilation area 5, 6 has several ventilation openings 7 continuously in direction along the longitudinal axis L of the ventilation band 1. The ventilation openings 7 are designed as elongated holes, but in principle another shape is also possible, e.g. round holes. The ventilation openings 7 are surrounded by a circumferential collar 8, which is to prevent moisture from entering the inner space in the roof through the ventilation openings 7 and which produces a spoiler function.

In the ventilation band 1, it has been ensured that inside the collar 8 there is arranged at least one circular, collar-shaped bulge 9 which surrounds the associated ventilation opening 7. Between the collar 8 and the bulge 9 there is a circular collector channel 10. As is particularly clear from fig. 3 and 4, the bulge 9 and thus the ventilation opening project above the collar 8. Otherwise, the walls 11, 12 of the bulge 9 which extend in the direction along the longitudinal axis L of the ventilation band 1 are directed towards each other. The angle of the walls 11, 12 is greater than 45° and less than 90° in relation to the horizontal direction. The bulge 9 is, like the collar 8, designed in one with the sealing area 3, 4, as is particularly clear from fig. 3 and 4.

As further appears from fig. 3 and 4, the attachment area 2, the sealing areas 3, 4 and the ventilation areas 5, 6 are produced in one piece from a flat plastic material. They consist of such a common material that the ventilation band 1 can be rolled up in the direction along the longitudinal axis L. The rolled up state of the ventilation band 1 is shown in fig. 5. It has been found that soft PVC which is stable against ultraviolet radiation and decay is favorable as a material for the ventilation band 1, as such a material enables easy assembly and perfect fit in the assembled state of the ventilation band 1.

As can be seen from the drawings, each sealing area 3, 4 has several loops 13 arranged along each other in the direction along the longitudinal axis L of the ventilation band 1. To form the loops 13, each sealing area 3, 4 has a fold at the end, the fold being cut to form the loops 13. The sections 13a between the loops 13 are arranged at an angle in relation to the longitudinal axis L of the ventilation band 1, so that the loops 13 are arranged correspondingly at an angle, which improves the sealing effect of the loops 13. Below the loops 13 is located on each side of the ventilation band 1 an adhesive strip 14, 15. The two adhesive strips 14, 15 are placed immediately on the lower leg of the loops 13, i.e. glued directly to the loops 13, so that a direct and firm connection is formed between each sealing area 3, 4 and the associated adhesive strip 14, 15.

In the embodiment shown, the bulge 9 is reinforced. The reinforcement can be formed in different ways, e.g. as a thickening of the walls 11,12. In the present case, the bulge 9 is reinforced by the fact that the walls 11, 12 are designed in a wave shape, the areas with the wave valleys 11a, 12a being more inclined in relation to the horizontal direction than the areas with the wave crests 11b, 12b.

As can be seen in particular from fig. 2, the distance a between two neighboring collars 8 is smaller than the length I of a collar 8. The distance b between two neighboring ventilation openings is in the present case greater than the length m of a ventilation opening 7.

As further appears from fig. 2, the adhesive strips 14, 15 run on the underside 16 of each sealing area 3, 4 in the direction along the longitudinal axis L of the ventilation band 1. A reinforcement 17, 18 is assigned to each of the sealing areas 3, 4. The reinforcement 17, 18 causes the sealing area 3, 4 which lies against the profile of the cover plates 19 on the roof retain their shape and not inadvertently move back, which would lead to an unwanted leak between the cover plates 19 on the roof and each sealing area 3, 4. Otherwise, it will be understood that the attachment area 2, the sealing areas 3, 4 and the ventilation areas 5 , 6 as well as the adhesive strips 14, 15 and the reinforcement 17, 18 run along the entire length of the ventilation band 1.

In the embodiment shown, each of the adhesive strips 14, 15 is equipped with the reinforcement 17, 18. Each reinforcement 17, 18 is thereby not a component of the sealing area 3, 4, but is only assigned to the relevant sealing area 3, 4 via each adhesive strip 14, 15 .

As can be seen in particular from fig. 3, the reinforcement 17, 18 is embedded in the associated adhesive strip 14, 15, so that the outer adhesive side 20, 21 of the adhesive strip 14, 15 is exclusively formed by the material in the adhesive strip 14, 15. In other words, this means that the reinforcement 17, 18 is not accessible from the outer adhesive side 20, 21.

Furthermore, it appears from fig. 2 that the reinforcement 17, 18 is formed as a wire insert of only a single wire. In the embodiment shown in fig. 2, the thread is regularly wavy. The waviness of the thread is such that the thread in a stretched state is approximately 1.4 times larger than in a wavy state. Due to the undulation of the thread, it is possible to achieve a stretching or "expansion" of the reinforcement 17, 18, to the extent that this is necessary for adaptation of each sealing area 3, 4 to the profile of the cover plates 19 on the roof.

As can be seen from fig. 3, a protective toll 22, 23 is placed on the outer adhesive side 20, 21 of the adhesive strip 14, 15, to ensure a problem-free installation of the ventilation band 1. The protective tolls 22, 23 are only removed at the end of the assembly process.

The installation of the ventilation band 1 according to the invention takes place by first unrolling the ventilation band 1 on a ridge batten 24. After correct alignment of the ventilation band 1, this is fixed to the ridge batten 24 via the attachment area 2, and especially riveted. Thus, the two sealing areas 3, 4 are pressed against the profile of the adjacent cover plates 19 on the roof, each reinforcement 17, 18 in the adhesive strips 14, 15 causing the sealing areas 3, 4 to retain their shape. The protective strips 22, 23 are then removed from the adhesive strips 14, 15 and the sealing areas 3, 4 are pressed so that a firm connection is formed between the sealing areas 3, 4 and the adjacent cover plates 19 on the roof. After mounting the ventilation band 1, the ridge stones 25 are placed over the ventilation band 1 and fixed.

Claims (14)

1. Ventilation band (1) for roofs, for installation in the ridge, hip or ridge area, with an attachment area (2), at least one outer sealing area (3, 4) and at least one between the sealing area (3, 4) and the attachment area (2) arranged ventilation area (5,6), the ventilation area (5,6) having several ventilation openings (7) arranged in the direction along the longitudinal axis (L) of the ventilation band (1), each of the ventilation openings (7) being arranged in a collar-shaped bulge (9), characterized in that the bulge (9) is surrounded by a circumferential collar (8), so that between the collar (8) and the bulge (9) a circumferential collector channel (10) is arranged. 2. Ventilation band as specified in claim 1, characterized in that the bulge (9) projects above the collar (8). 3. Ventilation band as stated in claim 1 or 2, characterized in that the walls (11,12) of the bulge (9) which extend in the direction along the longitudinal axis (L) of the ventilation band (1) are inclined towards each other, preferably at an angle greater than 45° and less than 90° in relation to the horizontal direction . 4. Ventilation band as specified in one of claims 1 to 3, characterized in that the collar (8) and/or the bulge (9) are designed in one with the ventilation area (5, 6). 5. Ventilation band as specified in one of claims 1 to 4, characterized in that the attachment area (2), the sealing area (3, 4) and the ventilation area (5, 6) are designed in one with the ventilation band (1) and consist of such a material that the ventilation band (1) can be rolled up in the direction along the longitudinal axis (L) . 6. Ventilation band as specified in one of claims 1 to 5, characterized in that the attachment area (2), the sealing area (3,4) and the ventilation area (5,6) consist of a soft PVC which is particularly stable against ultraviolet radiation. 7. Ventilation band as specified in one of claims 1 to 6, characterized in that the sealing area exhibits several loops (13) arranged along each other in the direction along the longitudinal axis (L) of the ventilation band (1). 8. Ventilation band as stated in claim 7, characterized in that the sealing area (3,4) is formed by a fold-in and that the fold-in is cut to form the loops (13,14), preferably so that the cuts between the loops (13) run at an angle. 9. Ventilation band as specified in one of claims 1 to 8, characterized in that the bulge (9) is reinforced, preferably in that the walls (11, 12) in the bulge (9) exhibit in the direction along the height of the bulge (9) projecting indentations, ribs or waves, the walls in the areas having indentations, ribs or waves are more inclined than in the outer areas which do not have impressions, ribs or waves. 10. Ventilation band as specified in one of claims 1 to 9, characterized in that the distance (a) between two neighboring collars (8) is less than the length (L) of a collar (8) and/or that the distance (b) between two neighboring ventilation openings (7) is greater than or equal to the length (m) to a ventilation opening (7), and that the ventilation openings (7) are each designed as elongated holes. 11. Ventilation band as specified in one of claims 1 to 10, characterized in that an adhesive strip (14,15) running in the direction along the longitudinal axis (L) of the ventilation band (1) is arranged on the underside of the sealing area (3, 4), and that a reinforcement (17, 18) is assigned to the sealing area (3, 4), in that the adhesive strip (14, 15) is preferably equipped with the reinforcement (17, 18), preferably in that the reinforcement (17, 18) is embedded in the adhesive strips (14, 15), in particular in that the reinforcement (17, 18) is so embedded in the adhesive strips (14, 15) that the outer adhesive side (20, 21) of the adhesive strip (14, 15) is exclusively formed from material in the adhesive strip (14, 15). 12. Ventilation band as specified in claim 11, characterized in that the reinforcement (17, 18) is designed as a wire insert, preferably with only one wire, the wire is preferably regularly wavy, twisted and/or sawtooth-like, the length of the wire in the stretched state is preferably at least 1.3 times greater than in the wavy, twisted and/or sawtooth-like state. 13. Ventilation band as specified in one of claims 11 or 12, characterized in that a protective toll (22, 23) is arranged on the adhesive side (20, 21) of the adhesive strip (14, 15). 14. Ventilation band as specified in one of claims 1 to 13, characterized in that a ventilation area (5, 6) and a sealing area (3, 4) are arranged on each side of the fastening strip (2).